SMART-1 D-CIXS To Planetary Science Archive Interface Control Document S1-CIX-RAL-ICD-3010 Issue 3.1 22 March 2010 Prepared by: Chris Perry / Harold Metselaar Approved by: Chris Howe Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 2 Distribution List Recipient Organisation Recipient ---------------------------------------------------------- D-CIXS Ops team RAL Chris Howe Chris Perry ESA PSA ESTEC Dave Heather Harold Metselaar DCIXS Science Team RAL Manuel Grande Barry Kellett Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 3 Change Log Date Sections Changed Reasons for Change ----------------------------------------------------------------- 27-Sept-2004 All First formal release 14-Oct-2005 Section 2 Description of new type 6 packet added. 29-Jan-2008 All Added Extended Mission Phase, added Time Standards, naming conventions, update of data products, added data products. 22-March All Updated all PSA related things, i.e. version PDS standard, Data Set IDÕs, Data Directory naming convention, File naming convention, Data Types (instrument modes), modified description of dataset directories, updates Chapter 4 and added example label files for each data product. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 4 Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 5 TBD ITEMS n/a Section Description D-CIXS EAICD Document No. Issue/Rev. No. Date Page S1-CIX-RAL-ICD-3010 3.1 22 March 2010 1 Table Of Contents 1 Introduction ______________________________________________________________________ 3 1.1 Purpose and Scope _______________________________________________________________ 3 1.2 Archiving Authorities ___________________________________________________________ 3 1.2.1 ESAÕs Planetary Science Archive (PSA) _________________________________________ 3 1.3 Contents ________________________________________________________________________ 3 1.4 Intended Readership _____________________________________________________________ 3 1.5 Scientific Objectives____________________________________________________________ 4 1.6 Applicable Documents_____________________________________________________________ 4 1.7 Relationships to Other Interfaces________________________________________________ 4 1.8 Acronyms and Abbreviations ______________________________________________________ 4 1.9 Contact Names and Addresses _____________________________________________________ 5 2 Overview of Instrument Design, Data Handling Process and Product Generation _______ 6 2.1 Hardware description ____________________________________________________________ 6 2.1.1 Detector Assembly _____________________________________________________________ 7 2.1.2 Radiation Shield and Controller _______________________________________________ 11 2.1.3 Solar Monitor _________________________________________________________________ 12 2.1.4 Data Processing Unit __________________________________________________________ 13 2.1.5 Summary of Instrument Operations ______________________________________________ 16 2.2 Scientific Objectives____________________________________________________________ 17 2.2.1 Lunar Science (Moon observation phase) ________________________________________ 17 2.2.2 Lunar plasma interaction (Moon Observation Phase) _____________________________ 18 2.2.3 The Earth's X-ray aurora: Argon line and N-S Conjugacy (Cruise Phase). ________ 18 2.2.4 The Earth's Magnetotail (Cruise Phase).________________________________________ 18 2.2.5 Astronomical Cruise Science with D-CIXS (Cruise Phase)_________________________ 18 2.2.6 XSM Solar Monitoring (Cruise Phase)____________________________________________ 18 2.2.7 Targets of Opportunity (Cruise Phase) _________________________________________ 19 2.2.8 Technology Objectives _________________________________________________________ 19 2.3 Data Handling Process ___________________________________________________________ 19 2.3.1 Data Levels ___________________________________________________________________ 20 2.3.2 Software:______________________________________________________________________ 20 2.4 Overview of Data Products _______________________________________________________ 22 2.4.1 Pre-Flight Data Products_______________________________________________________ 22 2.4.2 Instrument Calibrations________________________________________________________ 22 2.4.3 In-Flight Data Products________________________________________________________ 22 2.4.4 Software ______________________________________________________________________ 23 2.4.5 Documentation _________________________________________________________________ 23 2.4.6 Ancillary Data Usage __________________________________________________________ 23 3 Archive Format and Content_________________________________________________________ 24 3.1 Format and Conventions___________________________________________________________ 24 3.1.1 Deliveries and Archive Volume Format___________________________________________ 24 3.1.2 Data Set ID Formation _________________________________________________________ 24 3.1.3 Data Directory Naming Convention ______________________________________________ 25 3.1.4 Filenaming Convention__________________________________________________________ 25 D-CIXS EAICD Document No. Issue/Rev. No. Date Page S1-CIX-RAL-ICD-3010 3.1 22 March 2010 2 3.2 Standards Used in Data Product Generation _______________________________________ 26 3.2.1 PDS Standards _________________________________________________________________ 26 3.2.2 Time Standards ________________________________________________________________ 26 3.2.3 Reference Systems _____________________________________________________________ 27 3.2.4 Other Applicable Standards ____________________________________________________ 27 3.3 Data Validation _________________________________________________________________ 27 3.4 Content _________________________________________________________________________ 28 3.4.1 Volume Set ____________________________________________________________________ 28 3.4.2 Data Set_______________________________________________________________________ 29 3.4.3 Directories____________________________________________________________________ 29 4 Detailed Interface Specifications _________________________________________________ 32 4.1 Structure and Organization Overview _____________________________________________ 32 4.2 Data Sets, Definition and Content _______________________________________________ 32 4.3 Data Product Design Ð Common Information Elements _______________________________ 32 4.3.1 File Characteristics Data Elements ____________________________________________ 33 4.3.2 Data Object Pointers __________________________________________________________ 33 4.3.3 Identification Data Elements __________________________________________________ 33 4.3.4 Instrument and Detector Descriptive Data Elements _____________________________ 34 4.3.5 Positional information elements _______________________________________________ 34 4.4 Data Product Design Ð Header Data Element Descriptions __________________________ 34 4.4.1 Product Design Ð D-CIXS HK Time Series ________________________________________ 34 4.4.2 Product Design Ð D-CIXS Time Tagged X-Ray Data ________________________________ 39 4.4.3 Product Design Ð D-CIXS X-Ray Spectra Time Series _____________________________ 40 4.4.4 Product Design Ð Auxiliary Data _______________________________________________ 42 4.4.5 Product Design Ð Other Products _______________________________________________ 48 5 Appendix: Available Software to read PDS files ____________________________________ 48 6 Appendix___________________________________________________________________________ 49 6.1 Appendix A Example of Directory Listing of Data Set X ___________________________ 49 6.2 Appendix B Processing Levels ____________________________________________________ 49 6.3 Appendix C Example Data Products Descriptions____________________________________ 51 6.3.1 HK Time Series (S1_DCIXS_R00953_T00.LBL)_______________________________________ 51 6.3.2 Time Tagged Events (S1_DCIXS_R00953_T01.LBL) __________________________________ 79 6.3.3 Time Tagged X-Ray Data LCS (S1_DCIXS_R00953_T02.LBL) __________________________ 82 6.3.4 Time Tagged X-Ray Data HCS (S1_DCIXS_R00619_T03.LBL)___________________________ 85 6.3.5 Time Tagged X-Ray Data, Decompressed LCS (S1_DCIXS_R01403_T06.LBL) ____________ 88 6.3.6 X-Ray XSM Spectra (S1_DCIXS_R00953_T04.LBL) ___________________________________ 91 6.3.7 Auxiliary Data_________________________________________________________________ 95 Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 3 1 Introduction 1.1 Purpose and Scope The purpose of this EAICD (Experimenter Archive Interface Control Document) is two fold. 1. It provides users of the D-CIXS instrument with detailed description of the data products, a description of how they were generated, including data sources and destinations. As part of this information sufficient description of the instrument is provided to help in the interpretation of the data and corresponding caveats. 2. It is the official interface between the D-CIXS team and the ESA Planetary Science Archive (PSA). 1.2 Archiving Authorities The Planetary Data System Standard is used as archiving standard by ¥ NASA for U.S. planetary missions, implemented by PDS ¥ ESA for European planetary missions, implemented by the Research and Scientific Support Department (RSSD) of ESA For the purpose of archiving SMART-1 data, version 3.8 of the PDS standard is applicable. 1.2.1 ESAÕs Planetary Science Archive (PSA) ESA implements an online science archive, the PSA, ¥ To support and ease data ingestion ¥ To offer additional services to the scientific user community and science operations teams as e.g. o Search queries that allow searches across instruments, missions and scientific disciplines o Several data delivery options as ¥ Direct download of data products, linked files and data sets ¥ Ftp download of data products, linked files and data sets The PSA aims for online ingestion of logical archive volumes and will offer the creation of physical archive volumes on request. 1.3 Contents This document describes the data flow of the D-CIXS instrument on SMART-1 from the spacecraft through to insertion into the ESA PSA. It includes information on how data were processed, formatted, labelled and uniquely identified. The document discusses general naming schemes for data volumes, data sets, data and label files. Standards used to generate the product are explained. Software that may be used to access the product is explained further on. The design of the data set structure and the data product is given. 1.4 Intended Readership The intended readership for this EAICD is ¥ The staff of the archiving authority (Planetary Science Archive, ESA, RSSD, design team) ¥ Any potential user of the D-CIXS data. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 4 1.5 Scientific Objectives The detailed science objectives of the D-CIXS instrument are described in section 2.2. The core science objective is to demonstrate the technology required to produce absolute elemental abundance of the lunar surface. In addition the instrument shall be used during the cruise phase to monitor variations in the solar X-ray spectrum and to undertake X-ray observations of celestial sources, the Earth and objects of opportunity such as comets. 1.6 Applicable Documents AD1 Planetary Data System Preparation Workbook, February 1, 1995, Version 3.1, JPL, D7669, Part1 AD2 Planetary Data System Standards Reference, February 27, 2009, Version 3.8, JPL, D-7669, Part 2 AD3 Smart1 Archive Generation, Validation and Transfer Plan, July 7, 2003, Version 1.5, S1-EST-PL-1004 AD4 Navigation and Ancillary Information Facility (NAIF), http://pds-naif.jpl.nasa.gov AD5 Science Archive Review Procedure for EAICD/Cruise Phase, 12 October 2004, Version 3, S1-RSSD-PR-001 AD6 L1B Processor / Manager Software User Manual SOP-RSSD-UM-011 Draft b 23 May 2007 AD7 L1B Processor Software Configuration Language Definition SOP-RSSD-TN-034 Issue 1 b 23 May 2007 AD8 Quicklook Browse Tool for Level 1b Datasets, date, Version, SOP-RSSD-RP-032 DH D-CIXS/XSM Data Handling Interface Control Document, February 24, 2006, Version 13, S1-CIX-ICD-3002 UM D-CIXS DCIXS/XSM User Manual, October 16, 2002, Version 1.6, S1-CIX-MA-3002 XSM SMART-1 XSM, October 1, 2004, Version 11, S1-CIX-HY-ICD-0001 1.7 Relationships to Other Interfaces Changes in this document shall affect: ¥ D-CIXS data production pipeline ¥ D-CIXS archive volume production and delivery system 1.8 Acronyms and Abbreviations ADC Analogue to Digital Converter D-CIXS Demonstration Compact Imaging X-Ray Spectrometer DDS Data Distribution System DPU Data Processing Unit EEPROM Electrically Erasable Programmable Read-Only Memory FPGA Field Programmable Gate-Array GDP Generic Data Pipeline HK Housekeeping OBDH On Board Data Handling OBT On Board Time PROM Programmable Read-Only Memory Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 5 PSA Planetary Science Archive RAM Random Access Memory RICA Rosetta Ion Counter ASIC RSSD Research and Scientific Support Department SPICE Spacecraft, Planet, Instrument, C-matrix, Events TC Tele-Commands TM Telemetry XSM X-ray Solar Monitor 1.9 Contact Names and Addresses PI: Prof. Manuel Grande, University of Wales, M.Grande@aber.ac.uk, +44 1970 622624 Instrument Manager: Mr Chris Howe, RAL, c.j.howe@rl.ac.uk, +44 1235 44 5016 Instrument Scientist: Dr Barry Kellett, RAL, b.j.kellett@rl.ac.uk, +44 1235 44 6361 Archiving: Dr Chris Perry, RAL, c.h.perry@rl.ac.uk, +44 1235 44 5780 GDP: Ms Santa Martinez, ESA, S.Martinez@esa.int, +34 91 8131 118 Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 6 2 Overview of Instrument Design, Data Handling Process and Product Generation D-CIXS is a demonstration instrument aimed at proving the technology for a compact imaging spectrometer. As such there are many technical issues that must be taken into account when working with the data. In order to correctly utilise the data products for science analysis it is vital to have an understanding of the operation of the instrument and of the associated caveats provided with the data. This section provides a basic description of the instrument hardware and operation. 2.1 Hardware description A block diagram of the system configuration is shown in Figure 2-1. The instrument consists of two units: The DCIXS instrument comprises: DCIXS unit Ð The electronics unit including the DCIXS detectors. The main DCIXS instrument detector head consists of a matrix of 24 X-ray sensitive Swept Charge Devices (SCDs), integrated microstructure collimators to define and limit the field of view (FOV), and filters to inhibit background UV and solar wind ions and electrons. XSM Ð X-ray Solar Monitor on +X panel. The XSM Solar Monitor calibration unit is intended to provide direct observation of the Sun over a full range of phase angles and solar luminosities. The XSM has a wide spectral range (0.8 up to 20 keV) and good spectral resolution (about 200 eV at 6 keV obtainable). Measurement of low fluxes requires a large sensitive area detector. The incident fluorescence X-rays are detected by means of an array of 24 X-ray sensitive Swept Charge Devices (SCDs). The X-rays create electron-hole pairs and charge packets within the substrate in exactly the same way as in an X-ray sensitive CCD. The SCD is a newly developed large area (100mm2) single-pixel silicon X-ray detector. It has the same readout noise, and thus energy resolution characteristics of the very best customized X-ray CCD detectors. These devices can meet the performance requirements at Ônear roomÕ temperatures, 0¡ to 20¡ C. But when operating in a proton radiation environment protective measures have to be taken. The trapped and solar protons can generate vacancies in the silicon detector which act as charge trapping sites which degrade the performance in particular the energy resolution. The low energy protons that actually stop in the silicon cause the most damage and therefore a sliding shield to absorb them is moved over the detectors each time the trapped proton belts are entered. The energy resolution can be restored to a certain extent by increasing the signal readout integration period. The increased integration time also increases the system noise that has been offset by reducing the nominal operating temperature to ²-20¡C. The angular/spatial resolution is provided by a low profile (~3mm) collimator mounted directly above the SCDs. The energy of individual X-rays is recorded and the event time-tagged. Depending on the telemetry capacity available the individual event data is transmitted to ground or a spectrum is accumulated on board and then transmitted. The Solar X-ray monitor, which provides the measurement of the fluorescence excitation radiation, will measure the spectrum continuously with a 16s integration time. The data is time Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 7 tagged and transmitted, as it becomes ready. Further details of the XSM are covered in the separate XSM EAICD. Figure 2-1 DCIXS/XSM System <> 2.1.1 Detector Assembly A schematic of the detector assembly is shown in Figure 2-2. The detectors are mounted in a housing which acts as a heatsink and provides attenuation using gold plated shielding for the X-ray background generated as secondary products in local structure from primary cosmic ray flux. High-energy events depositing large amounts of charge within the detector are discriminated by threshold detection, so that although contributing to a detector dead time they do not produce background signal. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 8 <> Figure 2-2 Detector Assembly 2.1.1.1 Detectors Four SCDs are mounted on a ceramic substrate with the clocks and signal lines available on pins. See Figure 2-3. The detectors are mounted in small groups of four for ease of handling. <> Figure 2-3 Detector Configuration A summary of the SCDÕs characteristics is given in Table 2-1 SCD electrodes are arranged in a design that, upon clocking, will ÔsweepÕ any charge towards a low capacitance sense amplifier located in one corner of the detector (the bottom left-hand corner as shown in Figure 2-3). The design of the sense amplifier is again based upon that used in CCD technology, consisting of a very low capacitance sense amplifier and reset transistor, and again operates in exactly the same way as in a CCD. Readout noise as low as 3 electrons rms. A 100KHz readout rate can be anticipated as this has already been demonstrated in EEVÕs latest CCD designs. Table 2-1 Swept Charge Device Characteristics -------------------------------------------------------------- Sensitive area: 10 x 10 mm Max. Count rate: 30,000 counts/sec Output noise: 3 (typ.) to 5 (max.) electrons rms. (with 100KHz Correlated Double Sampling) Energy Resolution: 140eV Detector Efficiency: >30% at 280eV >30% at 10keV Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 9 Operating temperature: -10¡C to 0¡C -20¡C in proton radiation environment 2.1.1.2 Collimator Assembly The assembly consists of the low profile collimator layers interleaved with aluminium thin film filters which act as a visible light blocking filter preventing reflected solar light from entering the detector and also functions to absorb the background solar electrons. These are present at the collimator entrance at a flux of ~100 s-1 <> Figure 2-4 Collimator/Filter Configuration A total of 4000 of aluminium filter reduces the electron flux to essentially zero whilst allowing the transmission of 1-10keV fluorescence X-rays. For maximum electron suppression and immunity to pinholes, the filter is realised as two separate foils. Freestanding filters of this thickness would be far too fragile to survive launch thus a suitable mesh support is required. The collimators themselves make ideal filter support structures. 2.1.1.3 SCD Readout Electronics A block diagram of the front-end readout electronics is given in Figure 2-5. The SCD detectors are all operated in parallel under the control of a master waveform generator ASIC. This ASIC provides all the timing signals for driving the SCD electrodes, output amplifiers, the external correlated double sampling (CDS) signal processing electronics and analogue-to-digital converter (ADC). Digital control signals from the ASIC are level-shifted and buffered for driving the SCDÕs electrodes, again using circuitry already developed for CCD applications. The video signal from each SCD is taken to a CCD Signal Processor integrated circuit via a preamplifier. The signal processor performs the correlated double sampling and A/D conversion. The digitised data is fed through an ACTEL FPGA which performs data thresholding in the digital domain, and thus provides the first stage of data reduction by only passing on those data that are above a predefined, but programmable threshold. From the ACTEL, the data are passed to the Data Processor Unit (DPU). See Figure 2-1. <> Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 10 <> Figure 2-5 Swept Charged Device Readout System Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 11 2.1.2 Radiation Shield and Controller The detectors are protected from the lower energy protons, which will cause the most damage to the silicon detector material, by moving a 3mm thick tungsten shield in front as the trapped radiation belts are approached. It is opened again on leaving the belts. See Figure 2-6 <> Figure 2-6 Radiation Shield Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 12 2.1.3 Solar Monitor The sensor is an X-ray sensitive diode mounted on a Peltier cooler in a 13x9mm package behind a beryllium window. A front-end preamplifier is in the same detector package. Table 2-2 Detector Characteristics ---------------------------------------------- Sensor Silicon diode Area 0.28mm2 Thickness 0.5mm Energy Range 1keV to 20keV Energy Resolution 250eV at 6keV Window Circular Be 25¥m window Field of View 52¡ half cone angle Operating Peltier Cooled to -10¡C Temperature The detector is mounted in a larger package which contains another preamplifier stage. This package is mounted on the spacecraft. See Mechanical ICD S1-CIX-ICD-3004 2.1.3.1 Solar Monitor Electronics The system for processing the pulses from the detector and controlling the Peltier cooling of the sensor is contained on a single circuit board within the DCIXS unit. The system overview is given in Figure 2-7 <> Figure 2-7 XSM System Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 13 2.1.4 Data Processing Unit The Data Processor Unit (DPU) has design heritage from the ROSETTA MODULUS experiments. A block diagram of the DPU is given in Figure 2-8. It consists of an RTX2010 microprocessor with RAM, PROM, and EEPROM memory. The main functions of the unit are: ¥ To receive commands from the spacecraft OBDH, ¥ To provide control and timing synchronisation between the DCIXS detectors and the Solar Monitor, ¥ To receive data from both the DCIXS detector array and the Solar Monitor, and in software to provide a software histogram data compression and time tagging, ¥ To monitor the status and health of the instrument, and to provide housekeeping telemetry data, ¥ To pass data from the instrument to the main spacecraft OBDH. <> Figure 2-8 Data Processor System 2.1.4.1 Housekeeping Data Handling Temperature sensors, voltage monitors, and Spacecraft Power Supply Current monitor is conditioned and digitised on demand from the DPU via the internal backplane bus. The housekeeping parameters are given in S1-CIX-ICD-3002 Data Handling ICD and are one of the standard products to be provided to the PSA. 2.1.4.2 On-Board Software Description The on-board software is responsible for the control of the DCIXS & XSM experiments for periods of up to 4 days without Earth contact. It collects science and housekeeping data from the experiments and forwards these to the spacecraft. It receives, interprets and executes telecommands for the experiments and performs, autonomously, those actions that cannot be reasonably commanded during Earth contact or predicted sufficiently accurately to be handled by time-tagged telecommands. The software is designed to allow the most effective collection and transmission of science data by DCIXS and XSM consistent with instrument survivability and with the external constraints on resources placed on the instrument. The overall benefits of the mission are, Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 14 first, proving of the technology of the DCIXS and XSM experiments and, second, collection of data on solar X-ray flux (XSM) and Lunar soft X-ray emissions (DCIXS). The Lunar soft X-ray events (photons) have to be time tagged with sufficient accuracy to allow location of the source on the Moon. The Solar X-ray flux is required contemporaneously with the Lunar soft X-ray data for calibration purposes. During the (long) cruise to the Moon, certain astronomical sources will be observed by DCIXS for calibration and science purposes. One (the Crab Nebula) shall be at least two orders of magnitude brighter than the flux from the Moon. However, Solar X-ray flux and high accuracy time tagging of the soft X-ray photons is not required for the interpretation of these observations. The software provides separate modes (or sub-modes) of data acquisition/formatting to suit these different types of observation. The following general functions are required of the software: ¥ Receive, validate, interpret and execute DCIXS telecommands. ¥ Set up the instrument and electronics into the required operating state (usually in response to a TC). ¥ Acquire and collate science data from the DCIXS and XSM detectors and format into PUS packets for transmission. ¥ Gather analogue housekeeping data from the XSM and DCIXS electronics once per second. ¥ Once per second, monitor analogue housekeeping data. Report results in housekeeping TM. ¥ Take appropriate action when anomalies are detected. ¥ Format housekeeping data into PUS packets for transmission every 64 seconds. ¥ Maintain an on-board time reference synchronised with the Spacecraft on-board time to allow time stamping of TM packets and of DCIXS photon events (for correlation with attitude history). ¥ Maintain a history of instrument operation (TCs, events, anomalies) for subsequent transmission. ¥ Perform routine system health checks. ¥ Perform such autonomous actions as are necessary for the continued collection of useful science data. ¥ Respond to an external watchdog timer in the event of a software anomaly. ¥ Provide an emergency operating mode in the event of a system failure to enable diagnostic data to be transmitted and recovery procedures to be effected. The TCs must be acquired from the CAN-bus interface as CAN packets and assembled into PUS TC packets. Each of the TCs described in Data Handling ICD S1-CIX-ICD-3002 must be supported. On start-up or entry into standby or ROM-emergency mode, the on-board software must ensure that the XSM, DCIXS detector electronics and mechanisms are powered off. On entry into self-test or operating mode, the on-board software must optionally (as specific in the mode change TC) power on any selected combination of the XSM and the two DCIXS processing chains. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 15 The XSM must be set to its normal cooling mode. Also, at these transitions, the on-board software must load the correct waveform into the WGA, via the I2C interface on the RICA, and set up the FPGA and Analogue registers for each of the two DCIXS analogue processing chains. XSM: The on-board software must regularly read the XSM event FIFO, collating the events to produce a 512 element XSM spectrum every second. The 1 second spectra shall be combined to produce 16s spectra for downlink. DCIXS: The on-board software must regularly read the DCIXS event FIFO, depending on data formatting sub-mode and data rate, the events shall be reported either in a time-tagged event TM packets or in high or low rate spectra. Analogue HK values shall be collected from the DCIXS electronics and from the XSM electronics each second. Simple health checks shall be performed. The Each HK packet shall include the latest collected values for selected signals. If an analogue HK parameter exceeds a safety limit, the corresponding subsystem (XSM or DCIXS science electronics) should be switched off/disabled. No DCIXS analogue parameters have yet been identified for which a safety limit with corresponding action may be defined. The XSM leakage current must be monitored against a threshold, its rate of increase should also be checked against a second threshold. In operating mode, the DCIXS detector total counts should be summed and checked against a threshold to detect excessive ambient ionising radiation. Individual detector total counts should be checked against a limit to detect damage. If the XSM leakage current exceeds a threshold determined by two software parameters, which are monitored and updated during flight, the XSM must initiate an annealing sequence. After the sequence, XSM performs spectral calibration, updates the leakage current threshold, and returns to scheduled operation. The total duration of XSM annealing sequence is about 6 hours. If the total counts for 16 (software parameter) or more of the 24 DCIXS detector count totals exceeds a certain threshold (software parameter) the DCIXS detector door must be closed. The door shall be opened when the total count falls below a lower threshold (also a software parameter) for 8 (software parameter) or more detectors. If the total count for a particular detector should exceed a separate (software parameter) threshold, that detector shall be disabled and prevented from feeding data into the DCIXS RICA FIFO pending action/decision on the ground. A watchdog timer shall restart the on-board software in ROM-Emergency mode in case of a software crash. The software shall reset the timer no less often than once per second when executing correctly. The software must have an emergency operating mode that allows patching to RAM and dumping of memory locations. This mode shall be entered in case of a failed test at start-up or in case of a crash of the RAM-based software. The emergency mode should, if possible make no use of RAM or interrupts. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 16 2.1.5 Summary of Instrument Operations The operations envisaged for each phase of the mission are outlined in Table Table 2-3: Operations during each phase of the mission -------------------------------------------------------- LEOP Instrument Off Escape Continuous Thrust Instrument Off - radiation shields closed in radiation belts Escape Coast Arcs Radiation Shields closed in radiation belts DCIXS Calibration Astronomical observations XSM Solar Observations Auroral Observations DCIXS/XSM on-board calibrations Lunar Observation and Lunar Observation Extended Mission Astronomical observations DCIXS/XSM on-board calibrations The experiment modes are defined below. The DCIXS and XSM radiation shields should only be opened in OPERATING mode when prevailing radiation environment is acceptable. i.e. no large proton fluxes. The experiment modes and the data handling states are used during the mission phases as shown in Table 2-4. Table 2-4 Experiment Mode/Mission Phase Correlation --------------------------------------------------------------------------------------------------------------- Experiment Mode Mission Phase/ Pre-Launch LEOP EscapeContinuous EscapeCoast Arcs Lunar Observation and Experiment Data State Thrust Extended Mission ---------------------------------------------------------------------------------------------------------------- LAUNCH LOCK X X OFF X X X X EMERGENCY X X X STANDBY X X X SELF-TEST X X X OPERATIONAL DCIXS - Time tagged Event X X X Format DCIXS - Low Count Spectrum X X X Format DCIXS - High Count Spectrum X X X Format DCIXS - Autoformat [Default]X X X XSM X X X Housekeeping X X X Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 17 2.2 Scientific Objectives A summary of the D-CIXS science objectives is given in Table 2-5 and described in the following sub-sections. The prime observations are those taken during the lunar observation phase. The x-rays from the sun are absorbed by the lunar surface which in turn is stimulated to emit fluorescence X-rays characteristic of the elements which comprise the surface. The DCIXS instrument will simultaneously measure the solar X-ray flux and the emissions from the moon and will therefore able to produce a quantitative survey of the lunar surface materials as the spacecraft orbits the moon. Table 2-5: Summary of Scientific Objectives ---------------------------------------------------------------------------------------------- Observation Physical parameter Specific Performance Special Requirements Requirement ---------------------------------------------------------------------------------------------- Cruise Phase Auroral X-ray emissions Resolution of Argon Line Pointing of spacecraft Earth's X-ray aurora: required Argon line and N-S Conjugacy. Earth's Magnetotail. Electron flux Detection of high background levels of electrons by detectors Astronomical objects X-ray spectral time Nominal D-CIXS Pointing of spacecraft dependence performance required XSM Solar Monitoring Flare temporal evolution Nominal XSM and X-ray spectral performance variation Targets of X-ray spectra Nominal D-CIXS Pointing of spacecraft Opportunity performance required Lunar Observation Phase and Extended Mission Lunar geochemistry Spatial distribution of Nominal D-CIXS & XSM the major lunar rock performance types Lunar plasma X-ray emission from Nominal D-CIXS interaction impact of solar wind performance electrons on night side of moon 2.2.1 Lunar Science (Moon observation phase) The D-CIXS instrument will provide the first global map of the Moon in X-rays, with <50km spatial resolution at perilune (300km). It will map the absolute abundances of key elements across the Moon, such as Si, Mg, Al and Fe, and others in favourable (i.e. flare) conditions. It will provide far better energy resolution than that obtained with the Apollo 15/16 missions. Observations of these elements will help to constrain theories of lunar origin and evolution. Of fundamental importance is to determine the magnesium number [Mg/(Mg + Fe)] across the Moon which to date has not been achieved. We will also probe the geochemistry of the larger impact basins, one of which (the South Pole-Aitken basin) may contain exposed mantle material, and which exhibited unusual spectral signatures within the Clementine data. Vertical variations in crustal composition can be revealed by examination of impact crater ejecta and central peaks (as demonstrated by Clementine), which represent exhumed or exposed crustal material. We will be able to examine the deeper layers of the crust by studying the central peaks of the largest impact craters, and the central regions of the large impact basins. The time series of lava flows can reveal petrological evolution, and large scale observations of elemental variation across different lava flows in the maria will contribute to our understanding Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 18 of this evolution. These results will have direct relevance to lunar resource evaluation, as a precursor to future exploitation of the Moon as a base for space exploration. 2.2.2 Lunar plasma interaction (Moon Observation Phase) Recent Japanese X-ray observations of the Moon suggest that X-ray production on the night side due to the impact of energetic particles, while measurements by GGS/Wind and Lunar Prospector show that the energetic electrons of the solar wind are not shielded by the shadow, and that 1keV energy electrons are on occasion accelerated towards the surface. D-CIXS with its large effective area will provide the high-quality spectroscopy necessary to identify the processes. 2.2.3 The Earth's X-ray aurora: Argon line and N-S Conjugacy (Cruise Phase). Recent results from the X-ray emission of the aurora suggest that a significant portion of the X-ray flux it detects is due to the Argon line at 2.957 keV. This contaminates their efforts to deconvolute the incident electron spectrum and hence understand the global energetics. Spectra taken by DCIXS would clearly resolve this line, and hence remove the ambiguity. At distances up to about 18 Earth radii, DCIXS will be able to make measurements of the conjugacy of the northern and southern hemisphere X-ray aurora. These will be the first such measurements, and should again be of importance in understanding global auroral energy budgets. 2.2.4 The Earth's Magnetotail (Cruise Phase). DCIXS is shielded against electrons of energy up to 6 keV. Electrons more energetic than this are extremely rare in the solar wind. They do however occur in the magnetotail. While the increased background may degrade the X-ray performance of the instrument on the occasions when it enters the tail, there is interesting science to be done in mapping the structure of the tail. As the orbit is slowly increased from geostationary to lunar radius, the instrument will perform a detailed map of the width of the tail. 2.2.5 Astronomical Cruise Science with D-CIXS (Cruise Phase) There is scope for making important astronomical observations with D-CIXS. The one important area that D-CIXS can explore that is unlikely to be done by the current observatory- class X-ray missions (e.g. Chandra and XMM-Newton) is long duration monitoring campaigns. D-CIXS can monitor up to 15 or 20 sources for periods of up to 5 months (with daily observations) and can therefore alert the astronomical community to unusual or rare outburst phenomena on superluminal jet sources in AGN or other similar objects. D-CIXS can also monitor the much brighter galactic sources for spectral and time variability and again look for longer-term variability in these sources. This includes some of the brightest X-ray binary sources known which are now essentially beyond the limit of the very sensitive X-ray observatories (because they are too bright in X-rays). The proposed targets have been selected with the capabilities and limitations of the D-CIXS and SMART-1 in mind, and simulations have been made to be able to predict the observing times. Due to the large FOV without spatial resolution, the background contribution is estimated and the fields are checked for possible target confusion. All selected targets are significantly brighter than other targets in the 8x8 degree field. 2.2.6 XSM Solar Monitoring (Cruise Phase) Important cruise science will also be undertaken by the X-ray Solar monitor. The XSM spectral range is very sensitive to solar flare activity. During a flare the measured total spectrum is Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 19 largely dominated by the flux from the event, and the contribution from the solar network can be neglected, especially in the higher energies above about 3 keV. Thus we will be able to monitor the long-term evolution of flares, with the added dimension of good energy resolution (not possible with the current generation of GOES-type solar X-ray monitors). Such monitoring will complement the SOHO data very well. Long term monitoring of the X-ray spectral variability of the Sun excluding the flare events is also significant, especially in comparison with similar studies for other active stars. See the separate XSM EAICD for full details of the XSM instrument and archiving activities. 2.2.7 Targets of Opportunity (Cruise Phase) It is very likely that during the course of the SMART-1 cruise phase, a bright X-ray transient (sometimes referred to as X-ray Nova) will go off. Historically, such events occur about once per year. D-CIXS will then be able to provide the long-term monitor of such an event and provide detailed spectral evolution of the decline in X-rays. Again, these sources can be extremely bright close to maximum light and thus may be unobservable with other current X- ray instruments. Another possible important but unpredictable type of X-ray source would be a bright or near- Earth comet (such as comet Hyakutake in 1996 or Hale-Bopp in 1997). We know already that such sources are extremely erratic and variable and respond very quickly in changes to the solar wind and/or internal gas/dust outbursts. In these events, the X-rays are boosted and DCIXS will have the opportunity to make detailed spectral observations of the comet/outburst. The spectrum is certainly the vital "missing" ingredient that will allow the correct model for the X-ray production mechanism to be determined. 2.2.8 Technology Objectives The capability of these X-ray detectors, based on Swept Charged Devices, to withstand the space environment whilst maintaining good sensitivity will be proven by this mission. An in-flight calibration of the detectors is provided by the escape phase observations of well. known astronomical X-ray sources. The measurements made of the low flux levels from the lunar surface against the background of the solar wind electrons will demonstrate the design possibilities of the micro-collimation techniques. 2.3 Data Handling Process A description of the on-board data handling was provided under section 2.1.4. The data packets accumulated by the instrument are initially passed to the SMART-1 on-board data handling system where they are stored in a central solid state recorder in preparation for download to the ground. Contact with the ground station and down link of the science telemetry from occurs approximately twice a week. The instrument data packets together with spacecraft data and various auxiliary datasets (such as orbit, attitude, command logs and event files) are processed, catalogued and stored on the SMART-1 Data Distribution System (DDS) at ESOC. As part of this processing an additional binary header is pre-pended to each packet providing information on the ground receive station, packet time and quality. Data from the DDS is returned to the D-CIXS EOF either via a web based request procedure or through an automated request that automatically delivers new data. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 20 2.3.1 Data Levels The D-CIXS raw data (level 0) consists of a set of fixed length telemetry packets. Each packet is preceded by a packet header that includes information on the downlink time and contents of each packet. There are 10 packet types defined as listed in the Table 2-6. The packet types are described in S1-CIX-ICD-3002. Table 2-6 D-CIXS Level 0 Packet Types ------------------------------ Packet Type Description 0 Housekeeping 1 D-CIXS Time Tagged Events 2 D-CIXS Low Count Spectrum 3 D-CIXS High Count Spectrum 4 XSM Spectrum 5 Memory Dump 6 D-CIXS Compressed Low Count Spectrum 7 D-CIXS SCD Test 8 Auxiliary Data 9 Auxiliary Data Ð Detector Means The D-CIXS Level 1 data provided to the PSA shall consist of reformatted Level 0 data in PDS format. Where appropriate data shall be converted to engineering units using the standard conversion information specified in S1-CIX-ICD-3002 but will otherwise be uncalibrated. During October 2005 the onboard software was updated to add a new packet type. The previously unassigned Type 6 packet was created and set-up to contain a compressed D-CIXS low count spectrum. The detailed description of the contents and implementation of this new data type are described in S1-CIX-RAL-ECR-54 and the updated version of S1-CIX-ICD-3002. In the case of the Level 1 data the Type 6 packets will be decompressed prior to archival, the resulting output files resemble the existing Type 2 low count spectrum data, except for the binning of the data which is different. Therefore the decompressed Type 6 data will be archived as a product in its own right and not as a Type 2 product. The Level 2 data shall consists of calibrated X-ray events (time tagged mode) and spectra (time tagged, low and high count rate modes). The Level 3 data shall consist of lunar elemental abundance maps. This shall require deconvolution of the incident solar X-ray spectrum as measured by the XSM. 2.3.2 Software: In the following sections the software used for data processing is detailed. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 21 2.3.2.1 Calibration Software No calibration software will be delivered with the exception of: ¥ Decompression software for decompressing the type 6 data, i.e. Compressed Low Count Spectra. This will be provided in the EXTRAÕs directory, see section 3.4.3.8. ¥ Data used for the conversion from raw values to engineering units. This will be stored in the CALIB directory, see section 3.4.3.2. 2.3.2.2 Pipeline Processing Software ESA has made their Generic data Pipeline (GDP) available to process the telemetry data and is described hereunder see [AD6] for details. The GDP software is designed for the processing of telemetry data from instruments on board of ESA planetary spacecrafts. Telemetry data can be processed (selection, conversion, calibration, etc.) and converted into PDS compatible output data. The GDP supports the automated or manual processing of payload telemetry data files. It is not designed to be used as a real time tool. The software provides the following functionalities: GDP processor ------------- This program allows extracting data from a single telemetry data file, process the extracted data, and export the result in the form of one or more PDS compatible data file(s). The contents (structure) of the telemetry file, as well as the data which shall be extracted, and the structure of the PDS product are described in user-defined configuration files, see [AD7] for details. The GDP is started via the IDL or UNIX command line. Diagnostic output is produced in the command window and/or the IDL status window. Status and error messages are also saved in a log file. GDP manager ----------- This program is provided for the automated GDP processing of multiple telemetry data files in a UNIX/Linux environment. Selection criteria and processing parameters for the telemetry files are defined in a dedicated main configuration file. For each telemetry data file that meets the selection criteria, a dedicated GDP process is created. This process generated the desired PDS products in a specified directory. After successful process execution the telemetry file is moved to the destination directory. While the GDP processor can be used standalone for the manual processing of small numbers of data files, the combination of the GDP manager and processor allows for automatic processing of telemetry data in a SOC environment. 2.3.2.3 Scientific Analysis Software No scientific analysis software is part of the delivery to PSA. The QBTool is available for taking a quick look at the data. See [AD8] for details. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 22 2.4 Overview of Data Products This section provides an overview of the D-CIXS products that are to be included in the submission to the PDS. 2.4.1 Pre-Flight Data Products No deliveries of pre-flight data are planned. 2.4.2 Instrument Calibrations Instrument calibration data is included as part of the standard datasets that are delivered to the PDS. There are several different types of calibration information that shall be provided. ¥ Results of the onboard energy calibration run every 256s ¥ Data from detector covered by radioactive calibration source The onboard energy calibration information is returned in packets with specific data type ID that is only used to return this information. The data returned from the calibration source (spectral or time tagged) is included in the same data set as the other detectors that do not include the calibration source. However, each packet included the detector number allowing easy identification of the packets from the calibration detector. 2.4.3 In-Flight Data Products The in-flight data products that shall be provided as the initial delivery to the PSA shall consist of PDS formatted level 2 data products. These are raw or engineering level data that have been unpacked from the telemetry packets, time tagged, converted to engineering units and output in an easily readable form together with the necessary labels and auxiliary information required for ingestion into the PSA system. The science data has not been calibrated either for energy or for instrument efficiency factors so should not be directly used for science analysis without the application of the necessary calibration factors and algorithms. The data provided includes observations made during the cruise, lunar and extended mission phases. Cruise phase observations are mainly of celestial objects used to help assess the operational performance of the novel new technologies used within the D-CIXS experiment. In addition the cruise phase data includes a small number of Earth scan observations and attempts to detect X-ray emission from comets. Lunar and Extended Mission observations shall mainly include nadir pointing observations of the lunar surface. In addition it shall include ongoing observations of celestial targets to allow routine assessment of instrument performance. The level 2 data represents the full data set returned from the D-CIXS instrument. Descriptions of the individual products that are included in the level 2 submission to the PSA are provided in section 4.4 of this document. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 23 2.4.4 Software The D-CIXS processing software is based on the Generic data Pipeline (GDP) as provided by ESA see section 2.3.2.2 for details. The GDP is written mainly in IDL. The GDP will: ¥ Read the L1 telemetry files retrieved from the DDS ¥ Extract parameters from the telemetry packets and convert to L2 engineering units ¥ Re-package data and output L2 data in PDS format No software shall be provided with the datasets supplied to the PSA; however the data files conform to the standard PDS ASCII conventions and so can be read by software such as PDSREAD, and NASAVIEW see section 5 for details. 2.4.5 Documentation The following documentation shall be provided in the DOC directory. ¥ The EAICD ¥ Instrument papers ¥ Science papers ¥ The User Manual Summary documentation shall be provided in simple ASCII. Detailed documentation that includes complex formatting and diagrams shall only be provided as PDF. 2.4.6 Ancillary Data Usage The D-CIXS processing software requires timing information (e.g. time correlation) for production of any archived products including L2. The analysis of the D-CIXS data (both cruise and lunar operations) requires pointing information (orbit and attitude) as defined in the EID. This information is not required for the production of the L2 data products but is needed for any subsequent processing or analysis of these data (e.g. production of L3 data and lunar elemental abundance maps). The production of lunar elemental abundance information is dependent on the incident X-ray solar spectrum as measured by the XSM. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 24 3 Archive Format and Content 3.1 Format and Conventions 3.1.1 Deliveries and Archive Volume Format The D-CIXS data shall be delivered to the PSA as complete data sets (i.e. not using the release and revision concept). Transfer to the PSA shall be via ftp to the D-CIXS allocated drop point on the PSA server. The delivery schedule should be as agreed with the PSA (ref. PSA SMART-1 Archive Plan). The initial delivery shall consist of PDS Level 2 data. Three archive volumes shall be produced for each processing level, one covering the cruise phase observations that will consist mainly of astronomical observations, and two others covering the lunar operations phase of the mission, i.e the lunar phase and extended mission phase. 3.1.2 Data Set ID Formation Each PDS data set must have a unique identifier, DATA_SET_ID, formed from up to seven components and cannot exceed 40 characters in length. Each component of the DATA_SET_ID is an acronym, components are separated by hyphens. The components for each mission phase are listed in the table below. Table 3-1 Data Set ID Formation ----------------------------------------------------------------- Earth Escape Phase Lunar Phase Extended Mission Instrument host S1 S1 S1 Target X L L Instrument DCIXS DCIXS DCIXS Data processing 2 2 2 level number Data set type EDR EDR EDR (optional) Description EEP LP EP (optional) Version number V1.0 V1.0 V1.0 This gives the following DATA_SET_IDs ¥ S1-X-DCIXS-2-EDR-EEP-V1.0 ¥ S1-L-DCIXS-2-EDR-LP-V1.0 ¥ S1-L-DCIXS-2-EDR-EP-V1.0 Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 25 3.1.3 Data Directory Naming Convention The planned data directory struture shall be the same for all archive volumes defined in Section3.4.2. The scheme to be used shall be: For the Earth Escape Phase: EARTH_ESCAPE_yyyy_mm_TO_nn The subdirectory contains data from year yyyy month mm to month nn. Example EARTH_ESCAPE_2003_09_TO_12 Within the subdirectoriesthere is another subdirectory for each day of data. For the Lunar Phase and Extended Mission Phase: ORBIT_mmmmm_TO_nnnnn The subdirectory containing data from orbit mmmmm to orbit nnnnn in steps of 100 orbits. Each subdirectory in turn contains subdirectories for the individual orbits. Example ORBIT_00000_TO_00099 |---- ORBIT_00040 |---- ORBIT_00041 |---- ÉÉ |---- ORBIT_00092 |---- ORBIT_00097 3.1.4 Filenaming Convention For the Earth Escape Phase: S1_DCIXS___

_.EEE For the Lunar Phase and Extended Mission Phase: S1_DCIXS_R_.EEE Where: S1 = mission/spacecraft identifier DCIXS = instrument identifier = year (0000-9999) = month (01-12)

= day of month (01-31) = Txx where xx is the type number (see table below for details) = nnnnn (00000-99999), EEE = extension, TAB for the data products, LBL for the detached label file. = Txx where xx is the type number (see table below for details) Examples S1_DCIXS_2003_09_29_T03.TAB S1_DCIXS_R00099_T00.LBL Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 26 Table 3-2 Types used in data products ---------------------------------------------------------------- Packet Type Description Remarks Type number 0 00 Housekeeping 1 01 D-CIXS Time Tagged Events 2 02 D-CIXS Low Count Spectrum 3 03 D-CIXS High Count Spectrum 4 n/a XSM Spectrum Although the XSM data products are archived as a separate dataset the RAW XSM data is also archived as part of the DCIXS dataset. 5 n/a Memory Dump No product generated see section 4.4.5 for details. 6 06 D-CIXS Compressed Low Count Spectrum 7 n/a D-CIXS SCD Test No product generated see section 4.4.5 for details. 8 8A D-C1XS operating parameters Type 8 packets are split into two data products. 8 8B XSM operating parameters 9 9A Noise spectra Type 9 packets are split into two data products. 9 9B Detector means 3.2 Standards Used in Data Product Generation 3.2.1 PDS Standards PDS standard version 3.8 (February, 27, 2009) are used for the D-CIXS data archive production, see [AD1] and [AD2] for details. 3.2.2 Time Standards All time information in the data follows the SPICE time standards. Please, see [AD4] for details. Within the data products themselves, the time standard used is ET (Ephemeris Time), which is a double precision number of seconds. The starting point for this time is the J2000 epoch. This epoch is Greenwich noon on January 1, 2000 Barycentric Dynamical Time. This ephemeris time is calculated from the Spacecraft Onboard Time using the appropriate SPICE routines and the time correlation packages which are provided by ESA as a SPICE Clock Kernel. The main time values are provided in the data product labels, which provide a start and stop time for the measurement, and a corresponding clock count from the spacecraft. Below, the standards used to define these values are described. 3.2.2.1 START_TIME and STOP_TIME Formation The PDS formation rule for dates and time in UTC is: YYYY-MM-DDThh:mm:ss.fff Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 27 YYYY year (0000-9999) MM month (01-12) DD day of month (01-31) T date/time separator hh hour (00-23) mm minute (00-59) ss second (00-59) fff fractions of second (000-999) (restricted to 3 digits) This standard is followed for all START_TIME and STOP_TIME values in the products included in the D-CIXS data sets. 3.2.2.2 SPACECRAFT_CLOCK_START_COUNT and SPACECRAFT_CLOCK_STOP_COUNT The SPACECRAFT_CLOCK_START_COUNT and SPACECRAFT_CLOCK_STOP_COUNT values represent the on-board time counters (OBT) of the spacecraft and instrument computers. This OBT counter is given in the headers of the experiment telemetry source packets. It contains the data acquisition start time as 32-bit of unit seconds followed by 16-bit of fractional seconds. The time resolution of the fractional part is 2-16 = 1.52¥10-5 seconds. Thus, the OBT is represented as a decimal real number in floating-point notation with 5 digits after the decimal point. A reset of the spacecraft clock is represented by an integer number followed by a slash, e.g. "1/" or "2/". Example: SPACECRAFT_CLOCK_START_COUNT = "1/21983325.39258" 3.2.3 Reference Systems The reference systems used for orbit, attitude, and target body follow the SPICE standards and are defined in the different SPICE kernels. Please, see [AD4] for details. All latitudes and longitudes are given in degrees, latitudes are planetocentric. All geographical information in labels and index files will be given as follows: Sinusoidal projection, R= 1737.4, center latitude = 0, center longitude will be determined automatically using an integer value 3.2.4 Other Applicable Standards N/A 3.3 Data Validation The level 2 products that are proposed for the initial delivery to the PSA are essentially re-formatted raw data, where appropriate conversion factors have been applied to supply the data in engineering units. A basic set of checks have been applied to these data prior to conversion to the PDS standard to ensure that the data packets from which the parameters are derived are free from error (CRC check), complete and where necessary that all packets required in a multi-packet product have been received. No scientific qualification of the data has taken place at this level. The PVV tool provided by ESA will be used to validate the PDS archive. The Science Archive Review Procedure describes all review steps to be taken to ensure fulfillment of the long-term preservation purposes of ESA, see [AD5] for details. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 28 3.4 Content This section provides a description of the initial data volumes to be provided to the PSA and their content. The initial PSA delivery consists of reformatted level 1 data. 3.4.1 Volume Set The volume set constitutes three volumes as depicted below. For details on the naming conventions see the subsequent sections. VOLUME SET | | -------------------------------------------- | | | | | | ----------------- ---------------- ---------------- VOLUME VOLUME VOLUME S1DCIX_1001 S1DCIX_1002 S1DCIX_1003 VOLUME 1 SMART-1 VOLUME 2 SMART-1 VOLUME 3 SMART-1 D-CIXS CRUISE D-CIXS LUNAR D-CIXS EXTENDED SCIENCE DATA SCIENCE DATA SCIENCE DATA ----------------- ---------------- ---------------- Figure 3-1 Volume Set Three data volumes shall be provided for each level of data corresponding to the different phases of the mission. The Cruise Science volumes shall include all observations taken during the Earth escape phase. These include celestial observations, observations of the Earth and other solar system objects (e.g. attempts to observe objects of opportunity such as comets). Included within these observations are engineering, calibration and field of view tests which were undertaken as part of the checkout of the instrument and to help assess the technical performance of the instrument sub-systems. It should be noted that observations by the XSM (solar X-ray monitor) part of D-CIXS are archived in a separate volume provided by the XSM PI, although the uncalibrated EDR data shall also be included in the DCIXS level 2 product (type 4). The Lunar Science volumes shall include all observations taken during the Lunar observation phase of the mission. This will include lunar nadir pointing data as well as celestial calibration observations made to assess the ongoing performance and aging of the instrument sub-systems. Depending on planning observations in the lunar wake during eclipse may be undertaken in which case these data shall also be included in this volume. The Extended Mission volumes shall include all observations taken during the Extended Mission phase. This is basically a continuation of the Lunar Science phase. Table 3-3 Volume IDÕs and Names ------------------------------------------------------------------------------------------ Volume Set ID Volume Set Volume Name Volume ID Data Set ID Name ------------------------------------------------------------------------------------------ UK_RAL_CLRC_S1DCIX_1000 SMART-1 DCIXS VOLUME 1 SMART-1 S1DCIX_1001 S1-XDCIXS-2EDR-EEPV1.0 SCIENCE D-CIXS CRUISE DATA SCIENCE DATA VOLUME 2 SMART-1 S1DCIX_1002 S1-L-DCIXS-EDR-LPV1.0 D-CIXS LUNAR SCIENCE DATA VOLUME 3 SMART-1 S1DCIX_1002 S1-LDCIXS-2EDR-EPV1.0 D-CIXS EXTENDED SCIENCE DATA Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 29 3.4.2 Data Set Each volume consists of a single data set. Note that the PDS LEVEL 2 data identifier is the same as Level 1b described elsewhere in this and other PSA SMART-1 archive plan. See section 6.2 for a description of the different processing levels. Table 3-4 data Set IDÕs and Names ---------------------------------------------------------------------- Data Set ID Data Set Name ---------------------------------------------------------------------- S1-X-DCIXS-2-EDR-EEP-V1.0 SMART-1 D-CIXS LEVEL 2 CRUISE DATA V1.0 S1-L-DCIXS-2-EDR-LP-V1.0 SMART-1 D-CIXS LEVEL 2 LUNAR DATA V1.0 S1-L-DCIXS-2-EDR-EP-V1.0 SMART-1 D-CIXS LEVEL 2 EXTENDED DATA V1.0 ---------------------------------------------------------------------- 3.4.3 Directories This section describes the organisation and structure of the data volume to be delivered to the PDS. The structure shall be identical for the three differrent datasets. 3.4.3.1 Root Directory The contents of the ROOT directory shall follow the PDS specification. In addition to the standard directories (DOCUMENT, CATALOG, CALIB, GEOMETRY, INDEX and DATA) described in the following sections, the ROOT directory shall contain the files AAREADME.TXT, VOLDESC.CAT and ERRATA.TXT. 3.4.3.2 Calibration Directory No calibration data will be archived. 3.4.3.3 Catalog Directory The catalogue template objects providing high-level information about the data set shall be stored in the CATALOG directory. The catalogue directory shall include the following required files. These are based on the templates provided by the PSA CATINFO.TXT Identifies and describes the function of each file in the CALIB subdirectory. INST.CAT Brief description of instrument, one file for each instrument providing data to this delivery. DATASET.CAT Description of the data set currently being submitted, one file for each data product. INSTHOST.CAT Brief description of spacecraft and instrumentÕs mounting relationship to spacecraft. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 30 MISSION.CAT Description of mission and a summary of significant events during the mission. REF.CAT Bibliography. Other catalogues provide reference to these using keywords. PSA will produce central list for whole mission based on this information. PERSON.CAT Contains information about those persons responsible for the D-CIXS instrument and dataset. SOFTWARE.CAT A description of the software required to read/process this dataset. 3.4.3.4 Index Directory All the standard INDEX entries in this directory can be created by the PSA PVV tool. 3.4.3.4.1 Dataset Index File, INDEX.LBL and INDEX.TAB The dataset index files shall provide a full list of all files within the given data set. INDXINFO.TXT list of files in the INDEX directory 3.4.3.4.2 Geometric Index File, GEOINDEX.LBL and GEOINDEX.TAB Not included in the datasets. 3.4.3.4.3 Other Index Files No other index files are envisaged. 3.4.3.5 Browse Directory and Browse Files No browse products will be provide; no BROWSE directory will be included. 3.4.3.6 Geometry Directory The GEOMETRY directory contains the ancillary data products that are needed to reconstruct the DC1XS pointing information. This information was derived from inputs provided by ESA, e.g. SPICE files. There is one geometry table for each data product containing various geometry parameters for every 30 seconds. The SPICE kernels will be archived separately in the PSA. 3.4.3.7 Document Directory The DOCUMENT directory contains detailed documentation describing the instrument, datasets and software related to the volume. The documentation will be in PDF format and ASCII versions of the documentation shall also be provided. 3.4.3.8 EXTRA Directory In this directory ÒValue addedÓ elements included by the data preparer, but outside the scope of the PDS archive requirements. This directory contains: ¥ Explanation of the decompression of Type 6 data. ¥ A detailed target list. ¥ Explanation of the conversion to engineering units for HK data ¥ Elaboration of the S/C clock. 3.4.3.9 Data Directory See section 3.1.3 for information on the proposed directory-naming scheme. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 31 This directory should contain the data files corresponding to the products specified in section 4. Files shall be split into sub-directories based on year and month of observation Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 32 4 Detailed Interface Specifications This section describes the detailed specification of each of the level 2 products to be supplied to the PSA. As described in the previous section the products contained within the different observation datasets are essentially identical so no distinction has been made in this section between the different datasets. 4.1 Structure and Organization Overview A schematic overview of a dataset is given in Figure 4-1 below. For a description of the individual components see section 3.4. Figure 4-1Data Set TODO 4.2 Data Sets, Definition and Content As described in sub-sections under section 4.4 for the three datasets. 4.3 Data Product Design Ð Common Information Elements This section provides the description of the PDS product labels that are used to describe each of the PDS datasets that will be supplied to the PSA. In the following sub-sections we describe the different label elements that are common to all the supplied PDS labels that will be supplied by the D-CIXS EOF. These include the PDS version label, the file characteristic elements, data object pointers, identification information, instrument and detector descriptive information and positional data. The data object descriptions which are Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 33 the part of the label that are unique to each product within a dataset are described in section 4.4. Most of the labels have been given example values. See section 6.3 for examples for all data products. For some of the labels explanation comments where added. These comments are prefixed by a pound/number sign (Ò#Ó), and not part of the data definition. PDS_VERSION_ID = PDS3 4.3.1 File Characteristics Data Elements /*** FILE CHARACTERISTICS ***/ FILE_NAME = "S1_DCIXS_2005_01_19_T02.TAB" RECORD_TYPE = FIXED_LENGTH # All records in the data product file have the same length. RECORD_BYTES = 1060 FILE_RECORDS = 179 INTERCHANGE_FORMAT = ASCII # This label represents the manner in which data items are stored, for D-CIXS data products always ASCII. 4.3.2 Data Object Pointers /*** POINTERS TO DATA OBJECTS ***/ ^TABLE = ("S1_DCIXS_2005_01_19_T02.TAB",1) This indicates that the TABLE object (see for example section 4.4.1) points to the file S1_DCIXS_2005_01_19_T02.TAB. Pointers to data objects are always required to be located in the same directory as the label file, so the file in this example can be found the same directory as the detached label file. 4.3.3 Identification Data Elements /*** IDENTIFICATION DATA ELEMENTS ***/ DATA_SET_ID = S1-X-DCIXS-2-EEP-V1.0 DATA_SET_NAME = "SMART-1 OTHER DCIXS 2 EDR LUNAR V1.0" PRODUCT_ID = S1_DCIXS_2005_01_19_T00 PRODUCT_CREATION_TIME = 2007-12-13T10:19:41 PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" TARGET_NAME = MOON # This element identifies a target. Note that these can only take specific values specified in the PDS dictionary TARGET_TYPE = SATELLITE # The target type may be a planet, satellite, ring, region, feature, asteroid or comet. MISSION_PHASE_NAME = "LUNAR PHASE" # Possible values are: ("EARTH ESCAPE PHASE", "LUNAR PHASE", "EXTENDED MISSION") PRODUCT_TYPE = EDR START_TIME = 2005-01-18T13:18:49 STOP_TIME = 2005-01-18T13:31:01 SPACECRAFT_CLOCK_START_COUNT = 8/28339048.64 SPACECRAFT_CLOCK_STOP_COUNT = 8/28339780.4480ORBIT_NUMBER = 94 # The orbit number is "N/A" for Earth escape phase, for Lunar phase and Extended mission it is calculated, START_ORBIT_NUMBER = 94 # This provides the lowest revolution orbit number that contributed data to a given data product. STOP_ORBIT_NUMBER = 94 Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 34 # This provides the highest revolution orbit number that contributed data to a given data product. PRODUCER_ID = DCIXS_TEAM PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 # For processing levels see section 6.2. PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS AND DELIVERED AS HOUSE-KEEPING DATA" 4.3.4 Instrument and Detector Descriptive Data Elements /*** INSTRUMENT RELATED PARAMETERS ***/ INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" 4.3.5 Positional information elements /*** POSITIONAL INFORMATION ***/ RIGHT_ASCENSION = 106.544 DECLINATION = -70.448 WESTERNMOST_LONGITUDE = -117.672 EASTERNMOST_LONGITUDE = 139.625 MINIMUM_LATITUDE = -83.489 MAXIMUM_LATITUDE = 74.935 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 84.351 EMISSION_ANGLE = 13.636 LOCAL_HOUR_ANGLE = 323.046 SUB_SPACECRAFT_LONGITUDE = 51.511 SUB_SPACECRAFT_LATITUDE = -85.560 SPACECRAFT_ALTITUDE = 627.015 4.4 Data Product Design Ð Header Data Element Descriptions Values in the tables shall be separated by a Ò,Ó the START_BYTE and BYTES value should not include this within the column definition. 4.4.1 Product Design Ð D-CIXS HK Time Series The D-CIXS HKD product consists of a time series of over one hundred housekeeping parameters that describe the state of the instrument operation. The information contained in the PDS data file shall contain each of the parameters extracted from the D-CIXS HK telemetry packet, and where appropriate converted to engineering units using the conversion tables defined in the D-CIXS data handling ICD (S1_CIX_RAL_ICD_3002). Only a sub-set of the parameters are currently listed in the example object description provided below. OBJECT = TABLE INTERCHANGE_FORMAT = ASCII Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 35 ROWS = 293 # The rows element represents the number of rows in a data object, in PDS, the term 'rows' is synonymous with 'records'. ROW_BYTES = 831 # The row_bytes element represents the maximum number of bytes in each data object row. COLUMNS = 113 # The columns element represents the number of columns in each row of a data object, in the PDS, the term 'columns' is synonymous with 'fields'. NAME = "D-CIXS HK" DESCRIPTION = "D-CIXS HOUSEKEEPING DATA IN ENGINEERING UNITS" OBJECT = COLUMN BYTES = 23 # The bytes element indicates the number of bytes allocated for a particular data representation. DATA_TYPE = "TIME" # The data_type element supplies the internal representation and/or mathematical properties of a value being stored. NAME = "TIME" START_BYTE = 1 UNIT = "UT" # The unit element provides the full name or standard abbreviation of a unit of measurement in which a value is expressed. DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = DATA_TYPE = START_BYTE = BYTES = DESCRIPTION = FORMAT = UNIT = # units need to be in SI if applicable. END_OBJECT = COLUMN END_OBJECT = TABLE END Table 4-1 D-CIXS HK Parameter List ------------------------------------------------------------------------ NAME DESCRIPTION UNITS FORMAT TC_FLAGS TC error flags N/A Z4.4 SW_VER Software Version (divide by 10 = # F3.1 to get version e.g. 43 version 4.3) TC_OK TCs Accepted Count # I4 TC_REJ TCs rejected Count # I4 TC_ECODE TC Error Code # Z4.4 sw_flags-7 XSM processing 1= enabled # I1 sw_flags-6 DCIXS processing 1 = enabled # I1 sw_flags-5 Door radiation status 1=Shut # I1 sw_flags-4 Door radiation movement 1= Moving # I1 sw_flags-3 XSM shutter status 1= closed # I1 sw_flags-2 XSM entering annealing 1= annealing # I1 sw_flags-1 XSM on for >1s 1= true # I1 sw_flags-0 XSM switched on 1 = true # I1 CRC_BAD_R Received CRC from last TC packet # Z4.4 with bad CRC CRC_BAD_C Calculated CRC from last TC packet # Z4.4 with bad CRC DOOR_STATE Door State # I MODE Mode # I SUBMODE Submode # I MAX_CAN Max CAN packets in Output queue # I this HK period The following two parameters (TIME_ADJ1 and TIME_ADJ2) are combined into one. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 36 TIME_ADJ1 Last calculated time adjustment # I (high word) TIME_ADJ2 Last calculated time adjustment # I (low word) TIME_ADJF Last calculated time adjustment # I (fraction) TIME_WBG Worst background elapsed time this # I HK period TIME_WIDL Worst idle loop count this HK # I period CAN_NOT_READY Count of times CAN TX not ready # I LOST_PUS Count of lost TM PUS packets # I RET_STACK Return Stack pointer # Z4.4 PAR_STACK Parameter stack pointer # Z4.4 EEW_RETRY EEPROM write retries # I EEW_FAIL EEPROM write failures # I DOOR_CLS_DT Seconds remaining of minimum S I door closed interval LASTTC_TYPE Last TC Type # Z2.2 LASTTC_QUAL Last TC qualifier # Z2.2 LASTTC_ADDR Last TC Address/ function # Z4.4 LASTTC_DATA Last TC first data word # Z4.4 All four LASTTC parameters Z12 are combined into one and printed as hex. LASTTC1_TYPE Last but 1 TC Type # Z2.2 LASTTC1_QUAL Last but 1 TC qualifier # Z2.2 LASTTC1_ADDR Last but 1 TC Address/ function # Z4.4 LASTTC1_DATA Last but 1 TC first data word # Z4.4 All four LASTTC1 (last but one) Z12 parameters are combined and printed as hex. SEN16_OFF Sensor 16 inhibit # I1 SEN17_OFF Sensor 17 inhibit # I1 SEN18_OFF Sensor 18 inhibit # I1 SEN19_OFF Sensor 19 inhibit # I1 SEN20_OFF Sensor 20 inhibit # I1 SEN21_OFF Sensor 21 inhibit # I1 SEN22_OFF Sensor 22 inhibit # I1 SEN23_OFF Sensor 23 inhibit # I1 SEN08_OFF Sensor 8 inhibit # I1 SEN09_OFF Sensor 9 inhibit # I1 SEN10_OFF Sensor 10 inhibit # I1 SEN11_OFF Sensor 11 inhibit # I1 SEN12_OFF Sensor 12 inhibit # I1 SEN13_OFF Sensor 13 inhibit # I1 SEN14_OFF Sensor 14 inhibit # I1 SEN15_OFF Sensor 15 inhibit # I1 SEN00_OFF Sensor 0 # I1 SEN01_OFF Sensor 1 inhibit # I1 SEN02_OFF Sensor 2 inhibit # I1 SEN03_OFF Sensor 3 inhibit # I1 SEN04_OFF Sensor 4 inhibit # I1 SEN05_OFF Sensor 5 inhibit # I1 SEN06_OFF Sensor 6 inhibit # I1 SEN07_OFF Sensor 7 inhibit # I1 POWER_MON Power monitor # I BANK1A_CNT BANK 1 Channel A Event Count # I BANK1B_CNT BANK 1 Channel B Event Count # I BANK1C_CNT BANK 1 Channel C Event Count # I BANK1D_CNT BANK 1 Channel D Event Count # I BANK1E_CNT BANK 1 Channel E Event Count # I BANK1F_CNT BANK 1 Channel F Event Count # I BANK1G_CNT BANK 1 Channel G Event Count # I Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 37 BANK1H_CNT BANK 1 Channel H Event Count # I BANK1I_CNT BANK 1 Channel I Event Count # I BANK1J_CNT BANK 1 Channel J Event Count # I BANK1K_CNT BANK 1 Channel K Event Count # I BANK1L_CNT BANK 1 Channel L Event Count # I BANK2A_CNT BANK 2 Channel A Event Count # I BANK2B_CNT BANK 2 Channel B Event Count # I BANK2C_CNT BANK 2 Channel C Event Count # I BANK2D_CNT BANK 2 Channel D Event Count # I BANK2E_CNT BANK 2 Channel E Event Count # I BANK2F_CNT BANK 2 Channel F Event Count # I BANK2G_CNT BANK 2 Channel G Event Count # I BANK2H_CNT BANK 2 Channel H Event Count # I BANK2I_CNT BANK 2 Channel I Event Count # I BANK2J_CNT BANK 2 Channel J Event Count # I BANK2K_CNT BANK 2 Channel K Event Count # I BANK2L_CNT BANK 2 Channel L Event Count # I XSM_V_5 XSM +5V monitor V F5.2 XSM_V_12 XSM +12V monitor V F5.2 XSM_V_M12 XSM -12V monitor V F5.2 XSM_T_PIN XSM PIN detector temperature C F6.2 XSM_T_BOX XSM Detector Box temperature C F6.2 XSM_HV XSM HV Bias Voltage V F5.1 XSM_LEAK XSM Leakage Current pA F5.2 T_PSU DC Converter Temperature C F5.1 T_CANPCB CAN/HK PCB Temperature C F5.1 T_BOX -Y plate Temperature C F5.1 T_VIDPCB Video Digital PCB temperature C F5.1 T_3DP1 VIDEO1 3D+ temperature C F5.1 T_3DP2 VIDEO2 3D+ temperature C F5.1 T_SCDB SCD column B temperature C F5.1 T_SCDE SCD column E temperature C F5.1 V_12 12V regulated supply V F6.2 V_5 5V regulated supply V F5.2 V_3_3 3. 3V regulated supply V F5.2 XSM_V_PELT XSM Peltier supply voltage V F5.2 V_M12 -12V regulated supply V F6.2 V_M5 -5V regulated supply V F6.2 V_MOTOR_P1 Motor Phase 1 voltage V F5.1 V_MOTOR_P2 Motor Phase 2 voltage V F5.1 V_SCD_SS SCD Substrate Voltage Monitor V F5.2 V_SCD_OG SCD Output Gate Voltage Monitor V F5.2 V_SCD_RD SCD Reset Drain Voltage Monitor V F5.2 V_SCD_OD SCD Output Drain Voltage Monitor V F5.2 V_39 39V supply voltage [39V_ VMON] V F5.2 V_0 0V V F5.1 DOOR_LLL bit 1 Launch Lock Latch Enabled # A '1' = enabled DOOR_LLB bit 2 Launch Lock Bypass Enabled # A '1' = enabled DOOR_LLO bit 3 Launch Lock Latch Open # A = 1 [SW1] '1' = true DOOR_LLC bit 4 Launch Lock Latch Closed # A = 1 [SW2] '1' = true DOOR_MOTOR bit 5 Door Motor Running '1' # A = true DOOR_OPEN bit 6 Door Open '1' = true # A DOOR_CLOSED bit 7 Door Closed '1' = true # A DOOR_STEP Door Motor Step Count # I XSM_CMD_PELT bit 3 Peltier Control 1 = On # A or Heat 0 = Off & Cold XSM_CMD_SHUT bit 4 Shutter 1 = Open # A 0 = Closed Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 38 XSM_CMD_BIAS bit 5 HV Bias on/ off : 1= on 0 = off # A XSM_CMD_HVOVER bit 6 HV Override Enable: # A '1' = enabled '0' = Disabled XSM_CMD_FIFO bit 7 LSB FIFO write Enable: # A '1' = enabled '0' = Disabled XSM_OPEN bit 3 Shutter Open '1' = Open, 0 = - # A XSM_CLOSED bit 4 Shutter Closed '1' = Closed, # A 0 = - XSM_OVERT bit 5 Detector Overtemp HV should be # I switched down XSM_OVERV bit 6 HV bias overvoltage HV should # I be switched down XSM_ADC bit 7 LSB ADC Conversion complete # I XSM_DAC0 XSM DAC 0 (last value written to DAC) # Z XSM_DAC1 XSM DAC 1 (last value written to DAC) # Z XSM_STATE XSM State # I XSM_COUNT XSM second counter # I SW+PATCH Software Patch ID (added, # I in .xls not in table) BOOT_PG Boot Page Number (added, in .xls # I not in table) SS_DAC_AV SS DAC Monitor Average # I OG_DAC_AV OG DAC Monitor Average # I RD_DAC_AV RD DAC Monitor Average # I OD_DAC_AV OD DAC Monitor Average # I SS_DAC_REQ SS DAC demand # I OF_DAC_REQ OG DAC demand # I RD_DAC_REQ RD DAC demand # I OD_DAC_REQ OD DAC demand # I MS_LOST Milliseconds lost to 3D+ offset # I adjustment EVENTS_SEC Most events per second this period # I CK_SUMS Memory checksums # I Var_parameter Contents of address in Table 6 # Z param 55 ITL_ID ITL identity # 1 WGA_Status WGA status register contents # Z SCD_FIFO_2 SCD RICA FIFO port 2 register contents # Z SCD_FIFO_3 SCD RICA FIFO port 3 register contents # Z SCD_RICA SCD RICA software control register # Z contents XSM_Spectra XSM Spectra Count # I XSM_FIFO_2 XSM RICA FIFO port 2 register contents # Z XSM_FIFO_3 XSM RICA FIFO port 3 register contents # Z XSM_RICA XSM RICA software control register # Z contents Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 39 4.4.2 Product Design Ð D-CIXS Time Tagged X-Ray Data The D-CIXS time tagged science mode returns information on individual events detected by the sensors. For the PDS product, the events shall be unpacked and the spacecraft and time offset information used to calculate an absolute time for each event. The detector number, event signal (ADC bin number) and error flag information shall also be included. OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 25439 ROW_BYTES = 35 COLUMNS = "4" NAME = "D-CIXS TIME TAGGED EVENTS" DESCRIPTION = "D-CIXS TIME TAGGED EVENTS" OBJECT = COLUMN BYTES = 23 DATA_TYPE = "TIME" NAME = "TIME" START_BYTE = 1 UNIT = "UT" DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN BYTES = 2 DATA_TYPE = "ASCII_INTEGER" NAME = "DETECTOR" START_BYTE = 25 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = "23" VALID_MINIMUM = "00" END_OBJECT = COLUMN OBJECT = COLUMN BYTES = 4 DATA_TYPE = "ASCII_INTEGER" NAME = "X_RAY_SIGNAL" START_BYTE = 30 UNIT = "N/A" VALID_MAXIMUM = 4096 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 40 4.4.3 Product Design Ð D-CIXS X-Ray Spectra Time Series The D-CIXS energy spectrum object shall be used for data retrieved in both high, low count and compress low count spectra modes. The spectra consist of 256 energy levels (0 to 255) containing the number of events detected in the corresponding energy range within each integration period. The count information contained in the PDS data shall be decompressed from the internal compression scheme used within the telemetry format. Each spectrum shall have an associated start time and integration interval (normally fixed for low count spectra mode). /*** DATA CALIBRATION RELATED PARAMETERS ***/ /*** OBJECT DESCRIPTION ***/ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 179 ROW_BYTES = 1060 COLUMNS = 4 NAME = "DCIXS SPECTRA" DESCRIPTION = "DCIXS SPECTRA" OBJECT = COLUMN NAME = "START TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "START TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "INTEGRATION TIME" BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "SECONDS" DESCRIPTION = "INTEGRATION TIME" VALID_MAXIMUM = 9999 VALID_MINIMUM = 0008 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = "23" VALID_MINIMUM = "00" END_OBJECT = COLUMN OBJECT = COLUMN DESCRIPTION = "NUMBER OF X-RAY EVENTS in EACH OF THE 256 X-RAY SPECTRUM ELEMENTS" NAME = "EVENTS IN EACH X-RAY SPECTRUM ELEMENT" START_BYTE = 35 UNIT = "N/A" ITEMS = 255 ITEM_BYTES = 3 # 3 for LCS/DLCS, 9 for HCS DATA_TYPE = ASCII_INTEGER ITEM_OFFSET = 4 VALID_MAXIMUM = 255, 255 for LCS/DLCS, 134184960 for HCS (4095*2^15) VALID_MINIMUM = 0 END_OBJECT = COLUMN Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 41 END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 42 4.4.4 Product Design Ð Auxiliary Data The detector readout electronics configuration and noise parameters are transmitted in DCIXS telemetry packet types 8 and 9. They are transmitted whenever an offset adjustment is performed which for the default configuration is every 256s. The type 8 and type 9 packet data shall be combined and used to generate the following data products. 1. Offset calculation data 2. Noise Spectra 3. DCIXS operating parameters 4. XSM operating parameters This information is required to allow energy offset and energy calibration of the data to be calculated which is required to correctly use the spectral or time tagged data. 4.4.4.1 Offset Calculation Data As part of the processing activity the data values shall be re-ordered to put them in detector number order. OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = ROW_BYTES = fixed number COLUMNS = fixed number NAME = "D-CIXS OFFSET DATA" DESCRIPTION = "D-CIXS ZERO OFFSET CALCULATION PARAMETERS" OBJECT = COLUMN BYTES = 23 DATA_TYPE = "TIME" NAME = "TIME" START_BYTE = 1 UNIT = "UT" DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = DATA_TYPE = START_BYTE = BYTES = DESCRIPTION = FORMAT = UNIT = END_OBJECT = COLUMN END_OBJECT = TABLE END Table 4-2 D-CIXS Offset Parameter List ----------------------------------------------------------------------- TM PKT- NAME DESCRIPTION UNITS FORMAT Byte ----------------------------------------------------------------------- 8-16 SCD0_OFFSET SCD 0 zero position offset value # I 8-30 SCD1_OFFSET SCD 1 zero position offset value # I 8-44 SCD2_OFFSET SCD 2 zero position offset value # I 8-58 SCD3_OFFSET SCD 3 zero position offset value # I 8-18 SCD4_OFFSET SCD 4 zero position offset value # I 8-32 SCD5_OFFSET SCD 5 zero position offset value # I 8-46 SCD6_OFFSET SCD 6 zero position offset value # I Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 43 8-60 SCD7_OFFSET SCD 7 zero position offset value # I 8-20 SCD8_OFFSET SCD 8 zero position offset value # I 8-34 SCD9_OFFSET SCD 9 zero position offset value # I 8-48 SCD10_OFFSET SCD 10 zero position offset value # I 8-62 SCD11_OFFSET SCD 11 zero position offset value # I 8-72 SCD12_OFFSET SCD 12 zero position offset value # I 8-86 SCD13_OFFSET SCD 13 zero position offset value # I 8-100 SCD14_OFFSET SCD 14 zero position offset value # I 8-114 SCD15_OFFSET SCD 15 zero position offset value # I 8-74 SCD16_OFFSET SCD 16 zero position offset value # I 8-88 SCD17_OFFSET SCD 17 zero position offset value # I 8-102 SCD18_OFFSET SCD 18 zero position offset value # I 8-116 SCD19_OFFSET SCD 19 zero position offset value # I 8-76 SCD20_OFFSET SCD 20 zero position offset value # I 8-90 SCD21_OFFSET SCD 21 zero position offset value # I 8-104 SCD22_OFFSET SCD 22 zero position offset value # I 8-118 SCD23_OFFSET SCD 23 zero position offset value # I 8-126 SCD0_THRESHOLD SCD 0 detection threshold value # I 8-132 SCD1_THRESHOLD SCD 1 detection threshold value # I 8-138 SCD2_THRESHOLD SCD 2 detection threshold value # I 8-144 SCD3_THRESHOLD SCD 3 detection threshold value # I 8-128 SCD4_THRESHOLD SCD 4 detection threshold value # I 8-134 SCD5_THRESHOLD SCD 5 detection threshold value # I 8-140 SCD6_THRESHOLD SCD 6 detection threshold value # I 8-146 SCD7_THRESHOLD SCD 7 detection threshold value # I 8-130 SCD8_THRESHOLD SCD 8 detection threshold value # I 8-136 SCD9_THRESHOLD SCD 9 detection threshold value # I 8-142 SCD10_THRESHOLD SCD 10 detection threshold value # I 8-148 SCD11_THRESHOLD SCD 11 detection threshold value # I 8-166 SCD12_THRESHOLD SCD 12 detection threshold value # I 8-172 SCD13_THRESHOLD SCD 13 detection threshold value # I 8-178 SCD14_THRESHOLD SCD 14 detection threshold value # I 8-184 SCD15_THRESHOLD SCD 15 detection threshold value # I 8-168 SCD16_THRESHOLD SCD 16 detection threshold value # I 8-174 SCD17_THRESHOLD SCD 17 detection threshold value # I 8-180 SCD18_THRESHOLD SCD 18 detection threshold value # I 8-186 SCD19_THRESHOLD SCD 19 detection threshold value # I 8-170 SCD20_THRESHOLD SCD 20 detection threshold value # I 8-176 SCD21_THRESHOLD SCD 21 detection threshold value # I 8-182 SCD22_THRESHOLD SCD 22 detection threshold value # I 8-188 SCD23_THRESHOLD SCD 23 detection threshold value # I 8-222 SCD0_SD SCD 0 noise peak standard # I deviation value 8-224 SCD1_SD SCD 1 noise peak standard # I deviation value 8-226 SCD2_SD SCD 2 noise peak standard # I deviation value 8-228 SCD3_SD SCD 3 noise peak standard # I deviation value 8-230 SCD4_SD SCD 4 noise peak standard # I deviation value 8-232 SCD5_SD SCD 5 noise peak standard # I deviation value 8-234 SCD6_SD SCD 6 noise peak standard # I deviation value 8-236 SCD7_SD SCD 7 noise peak standard # I deviation value Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 44 8-238 SCD8_SD SCD 8 noise peak standard # I deviation value 8-240 SCD9_SD SCD 9 noise peak standard # I deviation value 8-242 SCD10_SD SCD 10 noise peak standard # I deviation value 8-244 SCD11_SD SCD 11 noise peak standard # I deviation value 8-246 SCD12_SD SCD 12 noise peak standard # I deviation value 8-248 SCD13_SD SCD 13 noise peak standard # I deviation value 8-250 SCD14_SD SCD 14 noise peak standard # I deviation value 8-252 SCD15_SD SCD 15 noise peak standard # I deviation value 8-254 SCD16_SD SCD 16 noise peak standard # I deviation value 8-256 SCD17_SD SCD 17 noise peak standard # I deviation value 8-258 SCD18_SD SCD 18 noise peak standard # I deviation value 8-260 SCD19_SD SCD 19 noise peak standard # I deviation value 8-262 SCD20_SD SCD 20 noise peak standard # I deviation value 8-264 SCD21_SD SCD 21 noise peak standard # I deviation value 8-266 SCD22_SD SCD 22 noise peak standard # I deviation value 8-268 SCD23_SD SCD 23 noise peak standard # I deviation value 9-14 SCD0_MEAN SCD 0 noise peak mean value # I 9-16 SCD1_MEAN SCD 1 noise peak mean value # I 9-18 SCD2_MEAN SCD 2 noise peak mean value # I 9-20 SCD3_MEAN SCD 3 noise peak mean value # I 9-22 SCD4_MEAN SCD 4 noise peak mean value # I 9-24 SCD5_MEAN SCD 5 noise peak mean value # I 9-26 SCD6_MEAN SCD 6 noise peak mean value # I 9-28 SCD7_MEAN SCD 7 noise peak mean value # I 9-30 SCD8_MEAN SCD 8 noise peak mean value # I 9-32 SCD9_MEAN SCD 9 noise peak mean value # I 9-34 SCD10_MEAN SCD 10 noise peak mean value # I 9-36 SCD11_MEAN SCD 11 noise peak mean value # I 9-38 SCD12_MEAN SCD 12 noise peak mean value # I 9-40 SCD13_MEAN SCD 13 noise peak mean value # I 9-42 SCD14_MEAN SCD 14 noise peak mean value # I 9-44 SCD15_MEAN SCD 15 noise peak mean value # I 9-46 SCD16_MEAN SCD 16 noise peak mean value # I 9-48 SCD17_MEAN SCD 17 noise peak mean value # I 9-50 SCD18_MEAN SCD 18 noise peak mean value # I 9-52 SCD19_MEAN SCD 19 noise peak mean value # I 9-54 SCD20_MEAN SCD 20 noise peak mean value # I 9-56 SCD21_MEAN SCD 21 noise peak mean value # I 9-58 SCD22_MEAN SCD 22 noise peak mean value # I Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 45 9-60 SCD23_MEAN SCD 23 noise peak mean value # I 4.4.4.2 Noise Spectra /*** OBJECT DESCRIPTION OBJECT = TABLE INTERCHANGE_FORMAT = "ASCII" ROWS = ROW_BYTES = COLUMNS = NAME = "NOISE PEAK SPECTRA" DESCRIPTION = "NOISE PEAK SPECTRA" OBJECT = COLUMN BYTES = 23 DATA_TYPE = "TIME" NAME = "TIME" START_BYTE = UNIT = "UT" DESCRIPTION = "TIME SPECTRUM CREATED" END_OBJECT = COLUMN OBJECT = COLUMN BYTES = "3" DATA_TYPE = "ASCII_INTEGER" NAME = "DETECTOR" START_BYTE = UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = "23" VALID_MINIMUM = "00" END_OBJECT = COLUMN OBJECT = COLUMN DESCRIPTION = "NUMBER OF NOISE EVENTS IN SPECTRUM" NAME = "NOISE SPECTRUM" START_BYTE = UNIT = "N/A" ITEMS = 108 ITEM_BYTES = "3" DATA_TYPE = "MSB_INTEGER" ITEM_OFFSET = 4 VALID_MAXIMUM = "255" VALID_MINIMUM = "0" END_OBJECT = COLUMN END_OBJECT = TABLE END 4.4.4.3 DCIXS Operating Parameters OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = ROW_BYTES = COLUMNS = NAME = "D-CIXS OPERATING PARAMETERS" DESCRIPTION = "D-CIXS OPERATING PARAMETERS" OBJECT = COLUMN BYTES = 23 DATA_TYPE = "TIME" NAME = "TIME" START_BYTE = 1 UNIT = "UT" DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = DATA_TYPE = START_BYTE = BYTES = DESCRIPTION = FORMAT = UNIT = END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 46 Table 4-3 DCIXS Operating Parameters --------------------------------------------------------------------- TM PKT NAME DESCRIPTION UNITS FORMAT --------------------------------------------------------------------- Byte 8-14 VIDEO_CONFIG1 SCD 0, 4 & 8 configuration # I 8-28 VIDEO_CONFIG2 SCD 1, 5 & 9 configuration # I 8-42 VIDEO_CONFIG3 SCD 2, 6 & 10 configuration # I 8-56 VIDEO_CONFIG4 SCD 3, 7 & 11 configuration # I 8-70 VIDEO_CONFIG5 SCD 12, 16 & 20 configuration # I 8-84 VIDEO_CONFIG6 SCD 13, 17 & 21 configuration # I 8-98 VIDEO_CONFIG7 SCD 14, 18 & 22 configuration # I 8-112 VIDEO_CONFIG8 SCD 15, 19 & 23 configuration # I 8-22 SCD0_GAIN SCD 0 video system gain # I 8-36 SCD1_GAIN SCD 1 video system gain # I 8-50 SCD2_GAIN SCD 2 video system gain # I 8-64 SCD3_GAIN SCD 3 video system gain # I 8-24 SCD4_GAIN SCD 4 video system gain # I 8-38 SCD5_GAIN SCD 5 video system gain # I 8-52 SCD6_GAIN SCD 6 video system gain # I 8-66 SCD7_GAIN SCD 7 video system gain # I 8-26 SCD8_GAIN SCD 8 video system gain # I 8-40 SCD9_GAIN SCD 9 video system gain # I 8-54 SCD10_GAIN SCD 10 video system gain # I 8-68 SCD11_GAIN SCD 11 video system gain # I 8-78 SCD12_GAIN SCD 12 video system gain # I 8-92 SCD13_GAIN SCD 13 video system gain # I 8-106 SCD14_GAIN SCD 14 video system gain # I 8-120 SCD15_GAIN SCD 15 video system gain # I 8-80 SCD16_GAIN SCD 16 video system gain # I 8-94 SCD17_GAIN SCD 17 video system gain # I 8-108 SCD18_GAIN SCD 18 video system gain # I 8-122 SCD19_GAIN SCD 19 video system gain # I 8-82 SCD20_GAIN SCD 20 video system gain # I 8-96 SCD21_GAIN SCD 21 video system gain # I 8-110 SCD22_GAIN SCD 22 video system gain # I 8-124 SCD23_GAIN SCD 23 video system gain # I 8-150 BANK1_REJECT SCD 0 to 11 event reject level # I 8-152 BANK1_THRESHOLD SCD 0 to 11 threshold mask # I 8-156 BANK1_COUNTERS SCD 0 to 11 counters control # I 8-160 SCD_VOD_DAC SCD OD voltage DAC # I 8-162 SCD_VRD_DAC SCD RD voltage DAC # I 8-164 BANK1_PWR Bank1 power control # I 8-190 BANK2_REJECT SCD 12 to 23 event reject level # I Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 47 8-192 BANK2_THRESHOLD SCD 12 to 23 threshold mask # I 8-196 BANK2_COUNTERS SCD 12 to 23 counters control # I 8-200 SCD_VOG_DAC SCD OG voltage DAC # I 8-202 SCD_VSS_DAC SCD SS voltage DAC # I 8-204 BANK2_PWR Bank2 power control # I 8-270 OFFSET_CALTIME Time to last Offset calibration s F8.4 (1/1024s units) 4.4.4.4 XSM Operating Parameters OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = ROW_BYTES = COLUMNS = NAME = "XSM OPERATING PARAMETERS" DESCRIPTION = "XSM OPERATING PARAMETERS IN ENGINEERING UNITS" OBJECT = COLUMN BYTES = 23 DATA_TYPE = "TIME" NAME = "TIME" START_BYTE = 1 UNIT = "UT" DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = DATA_TYPE = START_BYTE = BYTES = DESCRIPTION = FORMAT = UNIT = END_OBJECT = COLUMN END_OBJECT = TABLE END Table 4-4 XSM Operating Parameters ------------------------------------------------------------------------ TM PKT- NAME DESCRIPTION UNITS FORMAT Byte ------------------------------------------------------------------------ 8-206 XSM_PELTIER_DAC XSM default Peltier Target Tempr DAC # I o/p 8-207 XSM_DATA_THRSHLD XSM default Discriminator Threshold # I 8-208 XSM_HVBIAS_OFFTEMP XSM max. detector temperature to keep degC F4.1 HV bias on (Temp C = -Count*0.21875) 8-209 XSM_PKTGEN_THRSHLD XSM total count threshold for spectrum # I transmission 8-210 XSM_DELTA_I XSM delta leakage current threshold to pA F6.3 shut shutter (pA = Count * 0.78125) 8-211 XSM_I XSM max expected leakage current at pA F6.3 end of calibration (pA = Count * 0.78125) 8-212 XSM_I_SETTLE XSM leakage current settling time in s I seconds 8-213 XSM_SHTR_PULSES XSM number shutter pulses for # I autonomous activation Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 48 8-214 XSM_HVBIAS_ONTEMP XSM max safe PIN temperature for bias degC F4.1 switch-on (Temp C = - Count*0.21875) 8-215 XSM_CALTIME XSM calibration integration time in s I seconds 8-216 XSM_SHTR_TRIES XSM number of times to try shutter # I open/close 8-217 XSM_CAL_DELTA_I XSM margin for excess leakage current in pA F6.3 calibration (pA = Count * 0.78125) 8-218 XSM_ANNEAL_TIME XSM annealing period in seconds s I 8-219 XSM_ANNEAL_I_SETTLE XSM leakage current settling time before s I anealing 4.4.5 Product Design Ð Other Products XSM Sensor Data Ð Provision of the XSM data to the PSA is to be undertaken by the XSM team and is covered by a separate EAICD. However for level 2 data the XSM (Type 4) data shall also be supplied as part of the D-CIXS submission to the PSA. The PDS specification for this product can be found in [XSM]. The same data products as delivered by the XSM team will be delivered by the D-CIXS team as well. Memory Dump Ð This D-CIXS telemetry product provides dumps of the onboard DPU memory (Type 5). This is only useful for instrument engineering operations and shall not be delivered to the PSA. D-CIXS SCD Test Ð This is the output from the special D-CIXS TEST MODE (Type 7), which performs a long integration, fast readout of the swept charge devices to help assess their performance particularly with respect to radiation damage. This is primarily an engineering product and it will not be provided as part of the D-CIXS PSA products. 5 Appendix: Available Software to read PDS files NASAView NASAView is a PDS archive product display program that runs on multiple platforms in a GUI environment. PDSRead PDSRead was created at the Small Bodies Node (SBN) of the Planetary Data System (PDS) to read PDS image and data files. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 49 6 Appendix 6.1 Appendix A Example of Directory Listing of Data Set X This is an example for a data set; depending on the final outcome of what will be included in the PSA, updates may be necessary. ROOT DIRECTORY | |- VOLDESC.CAT |- AAREADME.TXT |- ERRATA.TXT | |- CATALOG | |- CATINFO.TXT | |- INST.CAT | |- DATASET.CAT | |- INSTHOST.CAT | |- MISSION.CAT | |- SOFTWARE.CAT | |- REF.CAT | |- PERSON.CAT | |- DATA | |- SUBDIRECTORIES_AS_REQUIRED [contains your data products] | |- INDEX | |-INDXINFO.TXT | |- INDEX.LBL [created by ESAÕs PVV tool] | |- INDEX.TAB [created by ESAÕs PVV tool] | |- DOCUMENT [contains supplementary and ancillary documents to help understand | the data products on the volume] | |- DOCINFO.TXT | |- DOCUMENTS_AS_REQUIRED | |- EXTRAS [contains additional items beyond the scope of the PDS requirements] | |- EXTRINFO.TXT | 6.2 Appendix B Processing Levels The table below lists the different PDS processing levels. Table 6-1 PDS Data Processing Levels --------------------------------------------------------------------- Level Type Processing Level Description 1 Raw Data Telemetry data with data embedded. 2 Edited Data Corrected for telemetry errors and split or decommutated into a data set for a given instrument. Sometimes called Experimental Data Record. Data are also tagged with time and location of acquisition. Corresponds to NASA Level 0 data. 3 Calibrated Edited data that are still in units produced by instrument, but that have Data been corrected so that values are expressed in or are proportional to some physical unit such as radiance. No resampling, so edited data can be reconstructed. NASA Level 1A. 4 Resampled Data that have been resampled in the time or space domains in such a Data way that the original edited data cannot be reconstructed. Could be calibrated in addition to being resampled. NASA Level lB. Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 50 5 Derived Derived results, as maps, reports, graphics, etc. NASA Levels 2 through 5. Data 6 Ancillary Nonscience data needed to generate calibrated or resampled data sets. Data Consists of instrument gains, offsets, pointing information for scan platforms, etc. 7 Correlative Other science data needed to interpret space-based data sets. May include Data ground based data observations such as soil type or ocean buoy measurements of wind drift. 8 User Description of why the data were required, any peculiarities associated with Description the data sets, and enough documentation to allow secondary user to extract information from the data. N N Not Applicable Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 51 6.3 Appendix C Example Data Products Descriptions The product labels for all products are listed in the following sub-sections. 6.3.1 HK Time Series (S1_DCIXS_R00953_T00.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T00.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 682 FILE_RECORDS = 146 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T00.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T00" PRODUCT_CREATION_TIME = 2010-01-28T18:27:02 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS AND DELIVERED AS HOUSEKEEPING DATA" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "DARK SKY" TARGET_TYPE = "N/A" START_TIME = 2005-07-26T22:23:13 STOP_TIME = 2005-07-27T00:58:57 SPACECRAFT_CLOCK_START_COUNT = "8/44701312.1088" SPACECRAFT_CLOCK_STOP_COUNT = "8/44701568.1088" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 319.713 DECLINATION = 64.813 WESTERNMOST_LONGITUDE = -177.443 EASTERNMOST_LONGITUDE = 171.709 MINIMUM_LATITUDE = -88.330 MAXIMUM_LATITUDE = 84.680 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.943 EMISSION_ANGLE = 47.459 LOCAL_HOUR_ANGLE = 254.379 SUB_SPACECRAFT_LONGITUDE = 43.942 SUB_SPACECRAFT_LATITUDE = 76.721 SPACECRAFT_ALTITUDE = 2825.427 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1007_T00_HK.tcf SM1_DCIXS_1007_T00_HK.dcf SM1_DCIXS_1007_T00_HK.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 146 ROW_BYTES = 682 COLUMNS = 107 NAME = "D-CIXS HK" DESCRIPTION = "D-CIXS Housekeeping Data in engineering units" OBJECT = COLUMN NAME = "UTC_TIME" COLUMN_NUMBER = 1 BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 DESCRIPTION = "START TIME OF MEASUREMENT (UTC)" FORMAT = "A23" UNIT = "UT" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TC_FLAGS" COLUMN_NUMBER = 2 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 DESCRIPTION = "TC ERROR FLAGS" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SW_VER" COLUMN_NUMBER = 3 BYTES = 3 DATA_TYPE = ASCII_REAL START_BYTE = 29 DESCRIPTION = "SOFTWARE VERSION" FORMAT = "F3.1" UNIT = "N/A" VALID_MAXIMUM = 6 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TC_OK" COLUMN_NUMBER = 4 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 33 DESCRIPTION = "TC ACCEPTED COUNTER" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TC_REJ" COLUMN_NUMBER = 5 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 37 DESCRIPTION = "TC REJECTED COUNTER" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 20 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TC_ECODE" COLUMN_NUMBER = 6 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 41 DESCRIPTION = "TC ERROR CODE" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SW_FLAGS_LB" COLUMN_NUMBER = 7 BYTES = 8 DATA_TYPE = CHARACTER START_BYTE = 45 DESCRIPTION = "THE SOFTWARE FLAGS LOW BYTE PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM EIGHT COMPONENTS (CHARACTERS): A0 A1 A2 A3 A4 A5 A6 A7 VALID ASSIGNMENTS FOR EACH COMPONENT ARE: A0: XSM PROCESSING (0=DISABLED,1=ENABLED) A1: DCIXS PROCESSING (0=DISABLED,1=ENABLED) A2: DOOR RADIATION STATUS (0=OPEN,1=SHUT) A3: DOOR RADIATION MOVEMENT(0=-,1=CLOSING) A4: XSM SHUTTER STATUS (0=OPEN,1=CLOSED) A5: XSM ENTERING ANNEALING(0=FALSE,1=TRUE) A6: XSM ON FOR >1s (0=FALSE,1=TRUE) A7: XSM SWITCHED ON (0=FALSE,1=TRUE)." FORMAT = "A8" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "CRC_BAD_R" COLUMN_NUMBER = 8 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 54 DESCRIPTION = "RECEIVED CRC FROM LAST TC PACKET WITH BAD CRC" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "CRC_BAD_C" COLUMN_NUMBER = 9 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 60 DESCRIPTION = "CALCULATED CRC FROM LAST TC PACKET WITH BAD CRC" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DOOR_STATE" COLUMN_NUMBER = 10 BYTES = 2 DATA_TYPE = CHARACTER START_BYTE = 66 DESCRIPTION = "THE DOOR STATE PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM TWO COMPONENTS: S E VALID ASSIGNMENTS FOR EACH COMPONENT ARE: S (DOOR SW STATE): 0 = OPEN 1 = CLOSING 2 = OPENING 3 = CLOSED 4 = SWITCH_FAIL E (DOOR E2 STATE): 0 = OPEN 1 = CLOSING 2 = OPENING 3 = CLOSED" FORMAT = "A2" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "MODE" COLUMN_NUMBER = 11 BYTES = 2 DATA_TYPE = CHARACTER START_BYTE = 69 DESCRIPTION = "THE MODE PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM TWO COMPONENTS: M S VALID ASSIGNMENTS FOR EACH COMPONENT ARE: M (SW MODE): 0 = STANDBY 1 = OPERATING 2 = TEST 3 = CALIBRATE 4 = RESTING S (SW SUBMODE): 0 = TIME_TAGGED 1 = LC_SPECTRUM 2 = HC_SPECTRUM 3 = LUNAR 4 = COMPRESSED_LC 5 = TT_3PIX 6 = TT 7 = HRLCS 8 = AUTO2" FORMAT = "A2" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "MAX_CAN" COLUMN_NUMBER = 12 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 72 DESCRIPTION = "MAX CAN PACKETS IN OUTPUT QUEUE THIS HK PERIOD" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 50 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TIME_ADJ" COLUMN_NUMBER = 13 BYTES = 10 DATA_TYPE = ASCII_INTEGER START_BYTE = 78 DESCRIPTION = "LAST CALCULATED TIME ADJUSTMENT" FORMAT = "I10" UNIT = "N/A" VALID_MAXIMUM = 134217727 VALID_MINIMUM = -134217728 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TIME_ADJF" COLUMN_NUMBER = 14 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 89 DESCRIPTION = "LAST CALCULATED TIME ADJUSTMENT (FRACTION) 65535THS OF A SECOND" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TIME_WBG" COLUMN_NUMBER = 15 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 95 DESCRIPTION = "WORST BACKGROUND ELAPSED TIME THIS HK PERIOD" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TIME_WIDL" COLUMN_NUMBER = 16 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 101 DESCRIPTION = "WORST IDLE LOOP COUNT THIS HK PERIOD" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "CAN_NOT_READY" COLUMN_NUMBER = 17 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 107 DESCRIPTION = "COUNT OF TIMES CAN TX NOT READY" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "LOST_PUS" COLUMN_NUMBER = 18 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 113 DESCRIPTION = "COUNT OF LOST TM PUS PACKETS" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "RET_STACK" COLUMN_NUMBER = 19 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 119 DESCRIPTION = "RETURN STACK POINTER" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "PAR_STACK" COLUMN_NUMBER = 20 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 123 DESCRIPTION = "PARAMETER STACK POINTER" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "EEW_RETRY" COLUMN_NUMBER = 21 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 127 DESCRIPTION = "EEPROM WRITE RETRIES" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "EEW_FAIL" COLUMN_NUMBER = 22 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 133 DESCRIPTION = "EEPROM WRITE FAILURES" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DOOR_CLS_DT" COLUMN_NUMBER = 23 BYTES = 10 DATA_TYPE = ASCII_INTEGER START_BYTE = 139 DESCRIPTION = "SECONDS REMAINING OF MINIMUM DOOR CLOSED INTERVAL" FORMAT = "I10" UNIT = "s" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SW_FLAGS_HB" COLUMN_NUMBER = 24 BYTES = 4 DATA_TYPE = CHARACTER START_BYTE = 150 DESCRIPTION = "THE SOFTWARE FLAGS HIGHBYTEPARAMETERISDEFINED" FORMAT = "A4" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DOOR_INT_CNT" COLUMN_NUMBER = 25 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 155 DESCRIPTION = "DOOR CLOSE INTEGRATOR COUNT" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "TIME_SINCE_CAL" COLUMN_NUMBER = 26 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 159 DESCRIPTION = "SECONDS SINCE LAST CALIBRATION" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "LAST_TC" COLUMN_NUMBER = 27 BYTES = 7 DATA_TYPE = ASCII_INTEGER START_BYTE = 165 DESCRIPTION = "LAST TC" FORMAT = "I7" UNIT = "N/A" VALID_MAXIMUM = 4294967295 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "LAST_TC1" COLUMN_NUMBER = 28 BYTES = 7 DATA_TYPE = ASCII_INTEGER START_BYTE = 173 DESCRIPTION = "LAST BUT 1 TC TYPE" FORMAT = "I7" UNIT = "N/A" VALID_MAXIMUM = 4294967295 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1623_OFF" COLUMN_NUMBER = 29 BYTES = 8 DATA_TYPE = ASCII_INTEGER START_BYTE = 181 DESCRIPTION = "THE SENSOR 16-23 INHIBIT PARAMETER IS DEFINED WITH A" FORMAT = "A8" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0815_OFF" COLUMN_NUMBER = 30 BYTES = 8 DATA_TYPE = ASCII_INTEGER START_BYTE = 190 DESCRIPTION = "THE SENSOR 8-15 INHIBIT PARAMETER IS DEFINED WITH A" FORMAT = "A8" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0007_OFF" COLUMN_NUMBER = 31 BYTES = 8 DATA_TYPE = ASCII_INTEGER START_BYTE = 199 DESCRIPTION = "THE SENSOR 0-7 INHIBIT PARAMETER IS DEFINED WITH A" FORMAT = "A8" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_PWR_STATUS" COLUMN_NUMBER = 32 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 208 DESCRIPTION = "POWER MONITOR" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_EVENTS" COLUMN_NUMBER = 33 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 212 DESCRIPTION = "BANK1 CHANNEL A EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_EVENTS" COLUMN_NUMBER = 34 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 218 DESCRIPTION = "BANK1 CHANNEL B EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_EVENTS" COLUMN_NUMBER = 35 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 224 DESCRIPTION = "BANK1 CHANNEL C EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_EVENTS" COLUMN_NUMBER = 36 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 230 DESCRIPTION = "BANK1 CHANNEL D EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_EVENTS" COLUMN_NUMBER = 37 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 236 DESCRIPTION = "BANK1 CHANNEL E EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_EVENTS" COLUMN_NUMBER = 38 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 242 DESCRIPTION = "BANK1 CHANNEL F EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_EVENTS" COLUMN_NUMBER = 39 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 248 DESCRIPTION = "BANK1 CHANNEL G EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_EVENTS" COLUMN_NUMBER = 40 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 254 DESCRIPTION = "BANK1 CHANNEL H EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_EVENTS" COLUMN_NUMBER = 41 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 260 DESCRIPTION = "BANK1 CHANNEL I EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_EVENTS" COLUMN_NUMBER = 42 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 266 DESCRIPTION = "BANK1 CHANNEL J EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_EVENTS" COLUMN_NUMBER = 43 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 272 DESCRIPTION = "BANK1 CHANNEL K EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_EVENTS" COLUMN_NUMBER = 44 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 278 DESCRIPTION = "BANK1 CHANNEL L EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_EVENTS" COLUMN_NUMBER = 45 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 284 DESCRIPTION = "BANK2 CHANNEL A EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_EVENTS" COLUMN_NUMBER = 46 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 290 DESCRIPTION = "BANK2 CHANNEL B EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_EVENTS" COLUMN_NUMBER = 47 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 296 DESCRIPTION = "BANK2 CHANNEL C EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_EVENTS" COLUMN_NUMBER = 48 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 302 DESCRIPTION = "BANK2 CHANNEL D EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_EVENTS" COLUMN_NUMBER = 49 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 308 DESCRIPTION = "BANK2 CHANNEL E EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_EVENTS" COLUMN_NUMBER = 50 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 314 DESCRIPTION = "BANK2 CHANNEL F EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_EVENTS" COLUMN_NUMBER = 51 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 320 DESCRIPTION = "BANK2 CHANNEL G EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_EVENTS" COLUMN_NUMBER = 52 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 326 DESCRIPTION = "BANK2 CHANNEL H EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_EVENTS" COLUMN_NUMBER = 53 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 332 DESCRIPTION = "BANK2 CHANNEL I EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_EVENTS" COLUMN_NUMBER = 54 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 338 DESCRIPTION = "BANK2 CHANNEL J EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_EVENTS" COLUMN_NUMBER = 55 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 344 DESCRIPTION = "BANK2 CHANNEL K EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_EVENTS" COLUMN_NUMBER = 56 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 350 DESCRIPTION = "BANK2 CHANNEL L EVENT COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_V_5" COLUMN_NUMBER = 57 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 356 DESCRIPTION = "XSM +5V MONITOR" FORMAT = "F10.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -2400 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_V_12" COLUMN_NUMBER = 58 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 367 DESCRIPTION = "XSM +12V MONITOR" FORMAT = "F10.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_V_M12" COLUMN_NUMBER = 59 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 378 DESCRIPTION = "XSM -12V MONITOR" FORMAT = "F10.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_T_PIN" COLUMN_NUMBER = 60 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 389 DESCRIPTION = "XSM PIN DETECTOR TEMPERATURE" FORMAT = "F10.1" UNIT = "C" VALID_MAXIMUM = 60 VALID_MINIMUM = -25 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_T_BOX" COLUMN_NUMBER = 61 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 400 DESCRIPTION = "XSM DETECTOR BOX TEMPERATURE" FORMAT = "F10.1" UNIT = "C" VALID_MAXIMUM = -270 VALID_MINIMUM = -280 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_HV" COLUMN_NUMBER = 62 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 411 DESCRIPTION = "XSM HV BIAS VOLTAGE" FORMAT = "F10.1" UNIT = "V" VALID_MAXIMUM = 0 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_LEAK" COLUMN_NUMBER = 63 BYTES = 10 DATA_TYPE = ASCII_REAL START_BYTE = 422 DESCRIPTION = "XSM LEAKAGE CURRENT" FORMAT = "F10.1" UNIT = "pA" VALID_MAXIMUM = 0.5 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_PSU" COLUMN_NUMBER = 64 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 433 DESCRIPTION = "DC CONVERTER TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_CANPCB" COLUMN_NUMBER = 65 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 439 DESCRIPTION = "CAN/HK PCB TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_BOX" COLUMN_NUMBER = 66 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 445 DESCRIPTION = "MY PLATE TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_VIDPCB" COLUMN_NUMBER = 67 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 451 DESCRIPTION = "VIDEO DIGITAL PCB TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_3DP1" COLUMN_NUMBER = 68 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 457 DESCRIPTION = "VIDEO1 3D+ TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_3DP2" COLUMN_NUMBER = 69 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 463 DESCRIPTION = "VIDEO2 3D+ TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 50 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_SCDB" COLUMN_NUMBER = 70 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 469 DESCRIPTION = "SCD COLUMN B TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 20 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T_SCDE" COLUMN_NUMBER = 71 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 475 DESCRIPTION = "SCD COLUMN E TEMPERATURE" FORMAT = "F5.1" UNIT = "C" VALID_MAXIMUM = 20 VALID_MINIMUM = -40 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_12" COLUMN_NUMBER = 72 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 481 DESCRIPTION = "12V REGULATED SUPPLY" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 12.5 VALID_MINIMUM = 11.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_5" COLUMN_NUMBER = 73 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 487 DESCRIPTION = "5V REGULATED SUPPLY" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 5.5 VALID_MINIMUM = 4.6 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_3_3" COLUMN_NUMBER = 74 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 493 DESCRIPTION = "3.3V REGULATED SUPPLY" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 3.5 VALID_MINIMUM = 3 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_V_PELT" COLUMN_NUMBER = 75 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 499 DESCRIPTION = "XSM PELTIER SUPPLY VOLTAGE" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 1.8 VALID_MINIMUM = 1.4 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_M12" COLUMN_NUMBER = 76 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 505 DESCRIPTION = "M12V REGULATED SUPPLY" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = -11.5 VALID_MINIMUM = -12.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_M5" COLUMN_NUMBER = 77 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 511 DESCRIPTION = "M5V REGULATED SUPPLY" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = -4.6 VALID_MINIMUM = -5.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_MOTOR_P1" COLUMN_NUMBER = 78 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 517 DESCRIPTION = "MOTOR PHASE 1 VOLTAGE" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 5 VALID_MINIMUM = -5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_MOTOR_P2" COLUMN_NUMBER = 79 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 523 DESCRIPTION = "MOTOR PHASE 2 VOLTAGE" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 5 VALID_MINIMUM = -5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_SCD_SS" COLUMN_NUMBER = 80 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 529 DESCRIPTION = "SCD SUBSTRATE VOLTAGE MONITOR" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_SCD_OG" COLUMN_NUMBER = 81 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 535 DESCRIPTION = "SCD OUTPUT GATE VOLTAGE MONITOR" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_SCD_RD" COLUMN_NUMBER = 82 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 541 DESCRIPTION = "SCD RESET DRAIN VOLTAGE MONITOR" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_SCD_OD" COLUMN_NUMBER = 83 BYTES = 6 DATA_TYPE = ASCII_REAL START_BYTE = 547 DESCRIPTION = "SCD OUTPUT DRAIN VOLTAGE MONITOR" FORMAT = "F6.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_32" COLUMN_NUMBER = 84 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 554 DESCRIPTION = "32V SUPPLY VOLTAGE" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -1 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "V_0" COLUMN_NUMBER = 85 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 560 DESCRIPTION = "0V" FORMAT = "F5.1" UNIT = "V" VALID_MAXIMUM = 0.5 VALID_MINIMUM = -0.5 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DOOR_MECH_STATUS" COLUMN_NUMBER = 86 BYTES = 5 DATA_TYPE = CHARACTER START_BYTE = 566 DESCRIPTION = "THE DOOR MECHANISM STATUS PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM FIVE COMPONENTS: B0 B1 B2 B3 B4 VALID ASSIGNMENTS FOR EACH COMPONENT ARE: B0: LAUNCH-LOCK LATCH ENABLED (0=DISABLED,1=ENABLED) B1: LAUNCH-LOCK BYPASS ENABLED (0=DISABLED,1=ENABLED) B2: LAUNCH-LOCK LATCH OPEN (0=FALSE,1=TRUE) B3: LAUNCH-LOCK LATCH CLOSED (0=FALSE,1=TRUE) B4: DOOR MOTOR RUNNING (0=FALSE,1=TRUE)" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DOOR_STEP" COLUMN_NUMBER = 87 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 572 DESCRIPTION = "DOOR MOTOR STEP COUNT" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_CONTROL" COLUMN_NUMBER = 88 BYTES = 5 DATA_TYPE = CHARACTER START_BYTE = 578 DESCRIPTION = "THE XSM CONTROL STATUS PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM FIVE COMPONENTS (CHARACTERS): B0 B1 B2 B3 B4 VALID ASSIGNMENTS FOR EACH COMPONENT ARE: B0: PELTIER SUPPLY (0=OFF,1=ON) B1: PELTIER MODE (0=COOL,1=HEAT) B2: HV BIAS (0=OFF,1=ON) B3: HV OVERRIDE (0=DISABLED,1=ENABLED) B4: XSM FIFO WRITE (0=DISABLED,1=ENABLED)" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_STATUS" COLUMN_NUMBER = 89 BYTES = 2 DATA_TYPE = CHARACTER START_BYTE = 584 DESCRIPTION = "THE XSM STATUS PARAMETER IS DEFINED WITH A CHARACTER STRING FORMED FROM TWO COMPONENTS (CHARACTERS): B0 B1 VALID ASSIGNMENTS FOR EACH COMPONENT ARE: B0: XSM DETECTOR OVER-TEMP (0=FALSE,1=TRUE) B1: XSM HV OVER-VOLTAGE (0=FALSE,1=TRUE)" FORMAT = "A2" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_DAC0" COLUMN_NUMBER = 90 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 587 DESCRIPTION = "XSM DAC 0 (LAST VALUE WRITTEN TO DAC)" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_DAC1" COLUMN_NUMBER = 91 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 591 DESCRIPTION = "XSM DAC 1 (LAST VALUE WRITTEN TO DAC)" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_STATE" COLUMN_NUMBER = 92 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 595 DESCRIPTION = "VALID ASSIGNMENTS FOR THE XSM STATE PARAMETER ARE: 0 = OFF 1 = STARTING 2 = COOLING 3 = COOL 4 = CALIBRATE 5 = OPENING 6 = OPERATING 7 = CLOSING 8 = HIGH-LEAKAGE 9 = PRE-ANNEAL 10 = ANNEAL 11 = CLOSING" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 15 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_SECONDS" COLUMN_NUMBER = 93 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 599 DESCRIPTION = "THE TIME XSM HAS BEEN IN ITS CURRENT STATE (SECONDS)" FORMAT = "I5" UNIT = "s" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SW_PATCH_ID" COLUMN_NUMBER = 94 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 605 DESCRIPTION = "SOFTWARE PATCH ID" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BOOT_PG" COLUMN_NUMBER = 95 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 609 DESCRIPTION = "THE PAGE NUMBER THAT THE SOFTWARE BOOTED FROM" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SS_DAC_AV" COLUMN_NUMBER = 96 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 613 DESCRIPTION = "SS DAC MONITOR AVERAGE" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OG_DAC_AV" COLUMN_NUMBER = 97 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 619 DESCRIPTION = "OG DAC MONITOR AVERAGE" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "RD_DAC_AV" COLUMN_NUMBER = 98 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 625 DESCRIPTION = "RD DAC MONITOR AVERAGE" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OD_DAC_AV" COLUMN_NUMBER = 99 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 631 DESCRIPTION = "OD DAC MONITOR AVERAGE" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SS_DAC_REQ" COLUMN_NUMBER = 100 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 637 DESCRIPTION = "SS DAC DEMAND" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OG_DAC_REQ" COLUMN_NUMBER = 101 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 641 DESCRIPTION = "OG DAC DEMAND" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "RD_DAC_REQ" COLUMN_NUMBER = 102 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 645 DESCRIPTION = "RD DAC DEMAND" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OD_DAC_REQ" COLUMN_NUMBER = 103 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 649 DESCRIPTION = "OD DAC DEMAND" FORMAT = "I3" UNIT = "N/A" VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "EVENTS_SEC" COLUMN_NUMBER = 104 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 653 DESCRIPTION = "MOST EVENTS/SEC THIS PERIOD" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "CK_SUMS" COLUMN_NUMBER = 105 BYTES = 10 DATA_TYPE = ASCII_INTEGER START_BYTE = 659 DESCRIPTION = "MEMORY CHECKSUMS" FORMAT = "I10" UNIT = "N/A" VALID_MAXIMUM = 0 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "T6PAR55" COLUMN_NUMBER = 106 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 670 DESCRIPTION = "DATA IN ADDRESS POINTED TO BY TABLE 6 PARAM. 55" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "ITL_ID" COLUMN_NUMBER = 107 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 676 DESCRIPTION = "ITL ID TABLE 6 PARAMETER 56" FORMAT = "I5" UNIT = "N/A" VALID_MAXIMUM = 65535 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 79 6.3.2 Time Tagged Events (S1_DCIXS_R00953_T01.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T01.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 33 FILE_RECORDS = 79716 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T01.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T01" PRODUCT_CREATION_TIME = 2010-01-31T14:13:00 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "DARK SKY" TARGET_TYPE = "N/A" START_TIME = 2005-07-26T22:05:46 STOP_TIME = 2005-07-27T00:26:10 SPACECRAFT_CLOCK_START_COUNT = "8/44634623.0" SPACECRAFT_CLOCK_STOP_COUNT = "8/44637327.0" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 0.000 DECLINATION = 0.000 WESTERNMOST_LONGITUDE = -179.971 EASTERNMOST_LONGITUDE = 174.516 MINIMUM_LATITUDE = -38.631 MAXIMUM_LATITUDE = 84.544 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 97.383 EMISSION_ANGLE = 0.000 LOCAL_HOUR_ANGLE = 0.006 SUB_SPACECRAFT_LONGITUDE = 44.455 SUB_SPACECRAFT_LATITUDE = 65.874 SPACECRAFT_ALTITUDE = 2875.716 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T01_TT.tcf SM1_DCIXS_1006_T01_TT.dcf SM1_DCIXS_1006_T01_TT.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 79716 ROW_BYTES = 33 COLUMNS = 3 NAME = "DCIXS TYPE 1 TIME TAGGED EVENTS" DESCRIPTION = "DCIXS SINGLE PIXEL TIME TAGGED EVENTS" OBJECT = COLUMN NAME = "TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" BYTES = 2 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = 23 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "X_RAY_SIGNAL" BYTES = 4 DATA_TYPE = ASCII_INTEGER START_BYTE = 28 UNIT = "N/A" VALID_MAXIMUM = 4095 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 82 6.3.3 Time Tagged X-Ray Data LCS (S1_DCIXS_R00953_T02.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T02.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 1315 FILE_RECORDS = 1870 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T02.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T02" PRODUCT_CREATION_TIME = 2010-02-06T11:42:07 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:34 STOP_TIME = 2005-07-27T00:55:50 SPACECRAFT_CLOCK_START_COUNT = "8/44701753.0" SPACECRAFT_CLOCK_STOP_COUNT = "8/44796224.0" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 252.696 DECLINATION = 56.096 WESTERNMOST_LONGITUDE = -139.895 EASTERNMOST_LONGITUDE = 46.916 MINIMUM_LATITUDE = -69.867 MAXIMUM_LATITUDE = 75.965 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.272 EMISSION_ANGLE = 9.005 LOCAL_HOUR_ANGLE = 99.742 SUB_SPACECRAFT_LONGITUDE = 43.456 SUB_SPACECRAFT_LATITUDE = 81.400 SPACECRAFT_ALTITUDE = 2777.313 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T02_LCS.tcf SM1_DCIXS_1006_T02_LCS.dcf SM1_DCIXS_1006_T02_LCS.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 1870 ROW_BYTES = 1315 COLUMNS = 4 NAME = "DCIXS SPECTRA" DESCRIPTION = "DCIXS SPECTRA" OBJECT = COLUMN NAME = "START TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "START TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "INTEGRATION TIME" BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "SECONDS" DESCRIPTION = "INTEGRATION TIME" VALID_MAXIMUM = 9999 VALID_MINIMUM = 8 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = 23 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN DESCRIPTION = "NUMBER OF X-RAY EVENTS IN EACH OF THE 256X-RAY SPECTRUM ELEMENTS" NAME = "EVENTS IN EACH X-RAY SPECTRUM ELEMENT" START_BYTE = 35 UNIT = "N/A" ITEMS = 256 ITEM_BYTES = 4 BYTES = 1279 DATA_TYPE = ASCII_INTEGER ITEM_OFFSET = 5 VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 85 6.3.4 Time Tagged X-Ray Data HCS (S1_DCIXS_R00619_T03.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00619_T03.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 2595 FILE_RECORDS = 52 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00619_T03.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00619_T03" PRODUCT_CREATION_TIME = 2009-08-10T07:35:30 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-05-19T01:50:06 STOP_TIME = 2005-05-19T01:57:06 SPACECRAFT_CLOCK_START_COUNT = "8/38752124.0" SPACECRAFT_CLOCK_STOP_COUNT = "8/38752544.0" ORBIT_NUMBER = 619 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 213.859 DECLINATION = 78.024 WESTERNMOST_LONGITUDE = 105.193 EASTERNMOST_LONGITUDE = 117.788 MINIMUM_LATITUDE = 70.081 MAXIMUM_LATITUDE = 72.185 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 81.322 EMISSION_ANGLE = 26.431 LOCAL_HOUR_ANGLE = 63.553 SUB_SPACECRAFT_LONGITUDE = 50.379 SUB_SPACECRAFT_LATITUDE = 82.043 SPACECRAFT_ALTITUDE = 2716.748 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T03_HCS.tcf SM1_DCIXS_1006_T03_HCS.dcf SM1_DCIXS_1006_T03_HCS.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 52 ROW_BYTES = 2595 COLUMNS = 4 NAME = "DCIXS HIGH COUNT SPECTRA" DESCRIPTION = "DCIXS HIGH COUNT SPECTRA" OBJECT = COLUMN NAME = "START TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "START TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "INTEGRATION TIME" BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "SECONDS" DESCRIPTION = "INTEGRATION TIME" VALID_MAXIMUM = 9999 VALID_MINIMUM = 0008 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = 23 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN DESCRIPTION = "NUMBER OF X-RAY EVENTS IN EACH OF THE 256 X-RAY SPECTRUM ELEMENTS" NAME = "X-RAY SPECTRUM ELEMENT" START_BYTE = 35 UNIT = "N/A" ITEMS = 256 ITEM_BYTES = 9 BYTES = 2559 DATA_TYPE = ASCII_INTEGER ITEM_OFFSET = 10 VALID_MAXIMUM = 134184960 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 88 6.3.5 Time Tagged X-Ray Data, Decompressed LCS (S1_DCIXS_R01403_T06.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R01403_T06.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 1315 FILE_RECORDS = 1937 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R01403_T06.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-EP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR EXTENDED DATA V1.0" PRODUCT_ID = "S1_DCIXS_R01403_T06" PRODUCT_CREATION_TIME = 2009-08-13T17:17:52 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "EXTENDED MISSION" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-10-28T05:47:06 STOP_TIME = 2005-10-28T08:21:22 SPACECRAFT_CLOCK_START_COUNT = "8/52745993.0" SPACECRAFT_CLOCK_STOP_COUNT = "8/52763901.0" ORBIT_NUMBER = 1403 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 81.022 DECLINATION = -47.195 WESTERNMOST_LONGITUDE = -179.661 EASTERNMOST_LONGITUDE = 145.135 MINIMUM_LATITUDE = -86.787 MAXIMUM_LATITUDE = 71.819 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 101.757 EMISSION_ANGLE = 24.851 LOCAL_HOUR_ANGLE = 217.253 SUB_SPACECRAFT_LONGITUDE = 76.263 SUB_SPACECRAFT_LATITUDE = -73.178 SPACECRAFT_ALTITUDE = 645.212 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T06_CLCS.tcf SM1_DCIXS_1006_T06_CLCS.dcf SM1_DCIXS_1006_T06_CLCS.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 1937 ROW_BYTES = 1315 COLUMNS = 4 NAME = "DCIXS SPECTRA" DESCRIPTION = "DCIXS SPECTRA" OBJECT = COLUMN NAME = "START TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "START TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "INTEGRATION TIME" BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "SECONDS" DESCRIPTION = "INTEGRATION TIME" VALID_MAXIMUM = 9999 VALID_MINIMUM = 0008 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 UNIT = "N/A" DESCRIPTION = "DETECTOR NUMBER" VALID_MAXIMUM = 23 VALID_MINIMUM = 0 END_OBJECT = COLUMN OBJECT = COLUMN DESCRIPTION = "NUMBER OF X-RAY EVENTS IN EACH OF THE 256X-RAY SPECTRUM ELEMENTS" NAME = "EVENTS IN EACH X-RAY SPECTRUM ELEMENT" START_BYTE = 35 UNIT = "N/A" ITEMS = 256 ITEM_BYTES = 4 BYTES = 1279 DATA_TYPE = ASCII_INTEGER ITEM_OFFSET = 5 VALID_MAXIMUM = 255 VALID_MINIMUM = 0 END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 91 6.3.6 X-Ray XSM Spectra (S1_DCIXS_R00953_T04.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T04.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 5157 FILE_RECORDS = 2 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T04.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T04" PRODUCT_CREATION_TIME = 2010-02-11T19:17:49 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:11 STOP_TIME = 2005-07-26T22:30:25 SPACECRAFT_CLOCK_START_COUNT = "8/44701730.0" SPACECRAFT_CLOCK_STOP_COUNT = "8/44808598.0" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 254.068 DECLINATION = 56.722 WESTERNMOST_LONGITUDE = 38.176 EASTERNMOST_LONGITUDE = 39.304 MINIMUM_LATITUDE = 76.308 MAXIMUM_LATITUDE = 76.854 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.324 EMISSION_ANGLE = 7.091 LOCAL_HOUR_ANGLE = 101.262 SUB_SPACECRAFT_LONGITUDE = 43.493 SUB_SPACECRAFT_LATITUDE = 81.153 SPACECRAFT_ALTITUDE = 2780.218 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T04_XSM.tcf SM1_DCIXS_1006_T04_XSM.dcf SM1_DCIXS_1006_T04_XSM.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 2 ROW_BYTES = 5157 COLUMNS = 6 NAME = "XSM SCIENCE DATA" DESCRIPTION = "XSM SCIENCE AND DIAGNOSTIC DATA" OBJECT = COLUMN NAME = "START TIME" BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 UNIT = UT DESCRIPTION = "START TIME OF OBSERVATION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "INTEGRATION TIME" BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 UNIT = "SECONDS" DESCRIPTION = "INTEGRATION TIME" VALID_MAXIMUM = 9999 VALID_MINIMUM = 0008 END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OVERTEMP HV" BYTES = 1 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 UNIT = "N/A" DESCRIPTION = "OVERTEMP HV" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OVERVOLTAGE HV" BYTES = 1 DATA_TYPE = ASCII_INTEGER START_BYTE = 33 UNIT = "N/A" DESCRIPTION = "OVERVOLTAGE HV" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "ADC CONVERSION" BYTES = 1 DATA_TYPE = ASCII_INTEGER START_BYTE = 35 UNIT = "N/A" DESCRIPTION = "ADC CONVERSION" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM SPECTRUM" START_BYTE = 37 UNIT = "N/A" ITEMS = 512 ITEM_BYTES = 9 BYTES = 5129 DATA_TYPE = ASCII_INTEGER ITEM_OFFSET = 10 VALID_MAXIMUM = 134184960 VALID_MINIMUM = 0 DESCRIPTION = "XSM SPECTRUM" END_OBJECT = COLUMN END_OBJECT = TABLE END Document No. S1-CIX-RAL-ICD-3010 Issue/Rev. No. 3.1 D-CIXS EAICD Date 22 March 2010 Page 95 6.3.7 Auxiliary Data 6.3.7.1 Offset Calculation Data (S1_DCIXS_R00953_T9B.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T9B.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 169 FILE_RECORDS = 35 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T9B.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T9B" PRODUCT_CREATION_TIME = 2010-02-05T03:20:48 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:28 STOP_TIME = 2005-07-27T00:55:52 SPACECRAFT_CLOCK_START_COUNT = "8/44701746.33856" SPACECRAFT_CLOCK_STOP_COUNT = "8/44813087.32832" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 253.072 DECLINATION = 56.270 WESTERNMOST_LONGITUDE = -140.047 EASTERNMOST_LONGITUDE = 46.952 MINIMUM_LATITUDE = -70.653 MAXIMUM_LATITUDE = 76.212 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.287 EMISSION_ANGLE = 8.473 LOCAL_HOUR_ANGLE = 100.143 SUB_SPACECRAFT_LONGITUDE = 43.467 SUB_SPACECRAFT_LATITUDE = 81.330 SPACECRAFT_ALTITUDE = 2778.136 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T09_AUX.tcf SM1_DCIXS_1006_T9B_AUX.dcf SM1_DCIXS_1006_T9B_AUX.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 35 ROW_BYTES = 169 COLUMNS = 25 NAME = "NOISE PEAK SPECTRA" OBJECT = COLUMN NAME = "UTC_TIME" COLUMN_NUMBER = 1 BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 DESCRIPTION = "START TIME OF MEASUREMENT (UTC)" FORMAT = "A23" UNIT = "UT" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_MEAN" COLUMN_NUMBER = 2 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 DESCRIPTION = "SCD0 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_MEAN" COLUMN_NUMBER = 3 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 DESCRIPTION = "SCD1 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_MEAN" COLUMN_NUMBER = 4 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 37 DESCRIPTION = "SCD2 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_MEAN" COLUMN_NUMBER = 5 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 43 DESCRIPTION = "SCD3 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_MEAN" COLUMN_NUMBER = 6 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 49 DESCRIPTION = "SCD4 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_MEAN" COLUMN_NUMBER = 7 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 55 DESCRIPTION = "SCD5 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_MEAN" COLUMN_NUMBER = 8 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 61 DESCRIPTION = "SCD6 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_MEAN" COLUMN_NUMBER = 9 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 67 DESCRIPTION = "SCD7 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_MEAN" COLUMN_NUMBER = 10 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 73 DESCRIPTION = "SCD8 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_MEAN" COLUMN_NUMBER = 11 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 79 DESCRIPTION = "SCD9 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_MEAN" COLUMN_NUMBER = 12 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 85 DESCRIPTION = "SCD10 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_MEAN" COLUMN_NUMBER = 13 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 91 DESCRIPTION = "SCD11 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_MEAN" COLUMN_NUMBER = 14 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 97 DESCRIPTION = "SCD12 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_MEAN" COLUMN_NUMBER = 15 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 103 DESCRIPTION = "SCD13 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_MEAN" COLUMN_NUMBER = 16 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 109 DESCRIPTION = "SCD14 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_MEAN" COLUMN_NUMBER = 17 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 115 DESCRIPTION = "SCD15 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_MEAN" COLUMN_NUMBER = 18 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 121 DESCRIPTION = "SCD16 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_MEAN" COLUMN_NUMBER = 19 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 127 DESCRIPTION = "SCD17 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_MEAN" COLUMN_NUMBER = 20 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 133 DESCRIPTION = "SCD18 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_MEAN" COLUMN_NUMBER = 21 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 139 DESCRIPTION = "SCD19 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_MEAN" COLUMN_NUMBER = 22 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 145 DESCRIPTION = "SCD20 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_MEAN" COLUMN_NUMBER = 23 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 151 DESCRIPTION = "SCD21 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_MEAN" COLUMN_NUMBER = 24 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 157 DESCRIPTION = "SCD22 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_MEAN" COLUMN_NUMBER = 25 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 163 DESCRIPTION = "SCD23 NOISE PEAK MEAN VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN END_OBJECT = TABLE END 6.3.7.2 Noise Spectra (S1_DCIXS_R00953_T9A.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T9A.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 569 FILE_RECORDS = 35 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T9A.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T9A" PRODUCT_CREATION_TIME = 2010-02-04T17:01:46 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:28 STOP_TIME = 2005-07-27T00:55:52 SPACECRAFT_CLOCK_START_COUNT = "8/44701746.33856" SPACECRAFT_CLOCK_STOP_COUNT = "8/44813087.32832" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 253.072 DECLINATION = 56.270 WESTERNMOST_LONGITUDE = -140.047 EASTERNMOST_LONGITUDE = 46.952 MINIMUM_LATITUDE = -70.653 MAXIMUM_LATITUDE = 76.212 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.287 EMISSION_ANGLE = 8.473 LOCAL_HOUR_ANGLE = 100.143 SUB_SPACECRAFT_LONGITUDE = 43.467 SUB_SPACECRAFT_LATITUDE = 81.330 SPACECRAFT_ALTITUDE = 2778.136 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T09_AUX.tcf SM1_DCIXS_1006_T9A_AUX.dcf SM1_DCIXS_1006_T9A_AUX.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 35 ROW_BYTES = 569 COLUMNS = 3 NAME = "NOISE PEAK SPECTRA" OBJECT = COLUMN NAME = "UTC_TIME" COLUMN_NUMBER = 1 BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 DESCRIPTION = "START TIME OF MEASUREMENT (UTC)" FORMAT = "A23" UNIT = "UT" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "DETECTOR" COLUMN_NUMBER = 2 BYTES = 3 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 DESCRIPTION = "DETECTOR NUMBER" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "NOISE_SPECTRUM" COLUMN_NUMBER = 3 BYTES = 539 DATA_TYPE = ASCII_INTEGER START_BYTE = 29 ITEMS = 108 ITEM_BYTES = 4 DESCRIPTION = "108 SAMPLES FROM THE DETECTOR IDENTIFIED IN PREVIOUS COLUMN" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" ITEM_OFFSET = 5 END_OBJECT = COLUMN END_OBJECT = TABLE END 6.3.7.3 D-CIXS Operating Parameters (S1_DCIXS_R00953_T8A.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T8A.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 727 FILE_RECORDS = 35 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T8A.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T8A" PRODUCT_CREATION_TIME = 2009-08-17T09:52:01 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:28 STOP_TIME = 2005-07-27T00:55:52 SPACECRAFT_CLOCK_START_COUNT = "8/44701746.33728" SPACECRAFT_CLOCK_STOP_COUNT = "8/44709026.32320" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 253.072 DECLINATION = 56.271 WESTERNMOST_LONGITUDE = -140.047 EASTERNMOST_LONGITUDE = 46.952 MINIMUM_LATITUDE = -70.653 MAXIMUM_LATITUDE = 76.212 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.287 EMISSION_ANGLE = 8.473 LOCAL_HOUR_ANGLE = 100.143 SUB_SPACECRAFT_LONGITUDE = 43.467 SUB_SPACECRAFT_LATITUDE = 81.330 SPACECRAFT_ALTITUDE = 2778.137 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T08_AUX.tcf SM1_DCIXS_1006_T8A_AUX.dcf SM1_DCIXS_1006_T8A_AUX.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 35 ROW_BYTES = 727 COLUMNS = 118 NAME = "C1XS OPERATIONAL PARAMETERS" DESCRIPTION = "C1XS OPERATIONAL PARAMETERS" OBJECT = COLUMN NAME = "UTC_TIME" COLUMN_NUMBER = 1 BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 DESCRIPTION = "START TIME OF MEASUREMENT (UTC)" FORMAT = "A23" UNIT = "UT" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG1" COLUMN_NUMBER = 2 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 DESCRIPTION = "SCD 0 4 AND 8 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG2" COLUMN_NUMBER = 3 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 DESCRIPTION = "SCD 1 5 AND 9 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG3" COLUMN_NUMBER = 4 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 37 DESCRIPTION = "SCD 2 6 AND 10 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG4" COLUMN_NUMBER = 5 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 43 DESCRIPTION = "SCD 3 7 AND 11 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG5" COLUMN_NUMBER = 6 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 49 DESCRIPTION = "SCD 12 16 AND 20 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG6" COLUMN_NUMBER = 7 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 55 DESCRIPTION = "SCD 13 17 AND 21 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG7" COLUMN_NUMBER = 8 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 61 DESCRIPTION = "SCD 14 18 AND 22 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "VIDEO_CONFIG8" COLUMN_NUMBER = 9 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 67 DESCRIPTION = "SCD 15 19 AND 23 CONFIGURATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_GAIN" COLUMN_NUMBER = 10 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 73 DESCRIPTION = "SCD0 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_GAIN" COLUMN_NUMBER = 11 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 79 DESCRIPTION = "SCD1 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_GAIN" COLUMN_NUMBER = 12 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 85 DESCRIPTION = "SCD2 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_GAIN" COLUMN_NUMBER = 13 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 91 DESCRIPTION = "SCD3 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_GAIN" COLUMN_NUMBER = 14 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 97 DESCRIPTION = "SCD4 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_GAIN" COLUMN_NUMBER = 15 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 103 DESCRIPTION = "SCD5 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_GAIN" COLUMN_NUMBER = 16 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 109 DESCRIPTION = "SCD6 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_GAIN" COLUMN_NUMBER = 17 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 115 DESCRIPTION = "SCD7 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_GAIN" COLUMN_NUMBER = 18 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 121 DESCRIPTION = "SCD8 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_GAIN" COLUMN_NUMBER = 19 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 127 DESCRIPTION = "SCD9 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_GAIN" COLUMN_NUMBER = 20 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 133 DESCRIPTION = "SCD10 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_GAIN" COLUMN_NUMBER = 21 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 139 DESCRIPTION = "SCD11 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_GAIN" COLUMN_NUMBER = 22 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 145 DESCRIPTION = "SCD12 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_GAIN" COLUMN_NUMBER = 23 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 151 DESCRIPTION = "SCD13 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_GAIN" COLUMN_NUMBER = 24 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 157 DESCRIPTION = "SCD14 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_GAIN" COLUMN_NUMBER = 25 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 163 DESCRIPTION = "SCD15 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_GAIN" COLUMN_NUMBER = 26 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 169 DESCRIPTION = "SCD16 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_GAIN" COLUMN_NUMBER = 27 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 175 DESCRIPTION = "SCD17 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_GAIN" COLUMN_NUMBER = 28 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 181 DESCRIPTION = "SCD18 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_GAIN" COLUMN_NUMBER = 29 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 187 DESCRIPTION = "SCD19 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_GAIN" COLUMN_NUMBER = 30 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 193 DESCRIPTION = "SCD20 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_GAIN" COLUMN_NUMBER = 31 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 199 DESCRIPTION = "SCD21 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_GAIN" COLUMN_NUMBER = 32 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 205 DESCRIPTION = "SCD22 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_GAIN" COLUMN_NUMBER = 33 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 211 DESCRIPTION = "SCD23 GAIN" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_OFFSET" COLUMN_NUMBER = 34 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 217 DESCRIPTION = "SCD0 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_OFFSET" COLUMN_NUMBER = 35 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 223 DESCRIPTION = "SCD1 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_OFFSET" COLUMN_NUMBER = 36 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 229 DESCRIPTION = "SCD2 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_OFFSET" COLUMN_NUMBER = 37 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 235 DESCRIPTION = "SCD3 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_OFFSET" COLUMN_NUMBER = 38 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 241 DESCRIPTION = "SCD4 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_OFFSET" COLUMN_NUMBER = 39 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 247 DESCRIPTION = "SCD5 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_OFFSET" COLUMN_NUMBER = 40 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 253 DESCRIPTION = "SCD6 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_OFFSET" COLUMN_NUMBER = 41 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 259 DESCRIPTION = "SCD7 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_OFFSET" COLUMN_NUMBER = 42 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 265 DESCRIPTION = "SCD8 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_OFFSET" COLUMN_NUMBER = 43 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 271 DESCRIPTION = "SCD9 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_OFFSET" COLUMN_NUMBER = 44 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 277 DESCRIPTION = "SCD10 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_OFFSET" COLUMN_NUMBER = 45 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 283 DESCRIPTION = "SCD11 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_OFFSET" COLUMN_NUMBER = 46 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 289 DESCRIPTION = "SCD12 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_OFFSET" COLUMN_NUMBER = 47 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 295 DESCRIPTION = "SCD13 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_OFFSET" COLUMN_NUMBER = 48 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 301 DESCRIPTION = "SCD14 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_OFFSET" COLUMN_NUMBER = 49 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 307 DESCRIPTION = "SCD15 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_OFFSET" COLUMN_NUMBER = 50 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 313 DESCRIPTION = "SCD16 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_OFFSET" COLUMN_NUMBER = 51 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 319 DESCRIPTION = "SCD17 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_OFFSET" COLUMN_NUMBER = 52 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 325 DESCRIPTION = "SCD18 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_OFFSET" COLUMN_NUMBER = 53 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 331 DESCRIPTION = "SCD19 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_OFFSET" COLUMN_NUMBER = 54 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 337 DESCRIPTION = "SCD20 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_OFFSET" COLUMN_NUMBER = 55 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 343 DESCRIPTION = "SCD21 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_OFFSET" COLUMN_NUMBER = 56 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 349 DESCRIPTION = "SCD22 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_OFFSET" COLUMN_NUMBER = 57 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 355 DESCRIPTION = "SCD23 OFFSET" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_THRESHOLD" COLUMN_NUMBER = 58 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 361 DESCRIPTION = "SCD0 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_THRESHOLD" COLUMN_NUMBER = 59 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 367 DESCRIPTION = "SCD1 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_THRESHOLD" COLUMN_NUMBER = 60 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 373 DESCRIPTION = "SCD2 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_THRESHOLD" COLUMN_NUMBER = 61 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 379 DESCRIPTION = "SCD3 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_THRESHOLD" COLUMN_NUMBER = 62 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 385 DESCRIPTION = "SCD4 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_THRESHOLD" COLUMN_NUMBER = 63 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 391 DESCRIPTION = "SCD5 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_THRESHOLD" COLUMN_NUMBER = 64 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 397 DESCRIPTION = "SCD6 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_THRESHOLD" COLUMN_NUMBER = 65 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 403 DESCRIPTION = "SCD7 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_THRESHOLD" COLUMN_NUMBER = 66 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 409 DESCRIPTION = "SCD8 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_THRESHOLD" COLUMN_NUMBER = 67 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 415 DESCRIPTION = "SCD9 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_THRESHOLD" COLUMN_NUMBER = 68 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 421 DESCRIPTION = "SCD10 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_THRESHOLD" COLUMN_NUMBER = 69 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 427 DESCRIPTION = "SCD11 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_THRESHOLD" COLUMN_NUMBER = 70 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 433 DESCRIPTION = "SCD12 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_THRESHOLD" COLUMN_NUMBER = 71 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 439 DESCRIPTION = "SCD13 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_THRESHOLD" COLUMN_NUMBER = 72 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 445 DESCRIPTION = "SCD14 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_THRESHOLD" COLUMN_NUMBER = 73 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 451 DESCRIPTION = "SCD15 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_THRESHOLD" COLUMN_NUMBER = 74 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 457 DESCRIPTION = "SCD16 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_THRESHOLD" COLUMN_NUMBER = 75 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 463 DESCRIPTION = "SCD17 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_THRESHOLD" COLUMN_NUMBER = 76 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 469 DESCRIPTION = "SCD18 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_THRESHOLD" COLUMN_NUMBER = 77 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 475 DESCRIPTION = "SCD19 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_THRESHOLD" COLUMN_NUMBER = 78 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 481 DESCRIPTION = "SCD20 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_THRESHOLD" COLUMN_NUMBER = 79 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 487 DESCRIPTION = "SCD21 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_THRESHOLD" COLUMN_NUMBER = 80 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 493 DESCRIPTION = "SCD22 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_THRESHOLD" COLUMN_NUMBER = 81 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 499 DESCRIPTION = "SCD23 DETECTION THRESHOLD" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD0_SD" COLUMN_NUMBER = 82 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 505 DESCRIPTION = "SCD0 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD1_SD" COLUMN_NUMBER = 83 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 511 DESCRIPTION = "SCD1 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD2_SD" COLUMN_NUMBER = 84 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 517 DESCRIPTION = "SCD2 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD3_SD" COLUMN_NUMBER = 85 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 523 DESCRIPTION = "SCD3 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD4_SD" COLUMN_NUMBER = 86 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 529 DESCRIPTION = "SCD4 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD5_SD" COLUMN_NUMBER = 87 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 535 DESCRIPTION = "SCD5 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD6_SD" COLUMN_NUMBER = 88 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 541 DESCRIPTION = "SCD6 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD7_SD" COLUMN_NUMBER = 89 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 547 DESCRIPTION = "SCD7 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD8_SD" COLUMN_NUMBER = 90 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 553 DESCRIPTION = "SCD8 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD9_SD" COLUMN_NUMBER = 91 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 559 DESCRIPTION = "SCD9 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD10_SD" COLUMN_NUMBER = 92 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 565 DESCRIPTION = "SCD10 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD11_SD" COLUMN_NUMBER = 93 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 571 DESCRIPTION = "SCD11 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD12_SD" COLUMN_NUMBER = 94 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 577 DESCRIPTION = "SCD12 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD13_SD" COLUMN_NUMBER = 95 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 583 DESCRIPTION = "SCD13 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD14_SD" COLUMN_NUMBER = 96 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 589 DESCRIPTION = "SCD14 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD15_SD" COLUMN_NUMBER = 97 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 595 DESCRIPTION = "SCD15 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD16_SD" COLUMN_NUMBER = 98 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 601 DESCRIPTION = "SCD16 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD17_SD" COLUMN_NUMBER = 99 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 607 DESCRIPTION = "SCD17 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD18_SD" COLUMN_NUMBER = 100 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 613 DESCRIPTION = "SCD18 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD19_SD" COLUMN_NUMBER = 101 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 619 DESCRIPTION = "SCD19 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD20_SD" COLUMN_NUMBER = 102 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 625 DESCRIPTION = "SCD20 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD21_SD" COLUMN_NUMBER = 103 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 631 DESCRIPTION = "SCD21 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD22_SD" COLUMN_NUMBER = 104 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 637 DESCRIPTION = "SCD22 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD23_SD" COLUMN_NUMBER = 105 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 643 DESCRIPTION = "SCD23 NOISE PEAK STANDARD DEVIATION" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK1_REJECT" COLUMN_NUMBER = 106 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 649 DESCRIPTION = "BANK 1 EVENT REJECT LEVEL" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK1_THRESHOLD" COLUMN_NUMBER = 107 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 655 DESCRIPTION = "SCD 0 TO 11 THRESHOLD MASK" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK1_COUNTERS" COLUMN_NUMBER = 108 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 661 DESCRIPTION = "SCD 0 TO 11 COUNTERS CONTROL" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD_VOD_DAC" COLUMN_NUMBER = 109 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 667 DESCRIPTION = "SCD OUTPUT DRAIN VOLTAGE DAC VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD_VRD_DAC" COLUMN_NUMBER = 110 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 673 DESCRIPTION = "SCD RESET DRAIN VOLTAGE DAC VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK1_PWR" COLUMN_NUMBER = 111 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 679 DESCRIPTION = "BANK 1 POWER CONTROL BITS" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK2_REJECT" COLUMN_NUMBER = 112 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 685 DESCRIPTION = "BANK 2 EVENT REJECT LEVEL" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK2_THRESHOLD" COLUMN_NUMBER = 113 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 691 DESCRIPTION = "SCD 12 TO 23 THRESHOLD MASK" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK2_COUNTERS" COLUMN_NUMBER = 114 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 697 DESCRIPTION = "SCD 12 TO 23 COUNTERS CONTROL" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD_VOG_DAC" COLUMN_NUMBER = 115 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 703 DESCRIPTION = "SCD OUTPUT GATE VOLTAGE DAC VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "SCD_VSS_DAC" COLUMN_NUMBER = 116 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 709 DESCRIPTION = "SCD SUBSTRATE VOLTAGE DAC VALUE" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "BANK2_PWR" COLUMN_NUMBER = 117 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 715 DESCRIPTION = "BANK 2 POWER CONTROL BITS" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "OFFSET_CALTIME" COLUMN_NUMBER = 118 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 721 DESCRIPTION = "TIME TO LAST OFFSET CALIBRATION (1/1024 SECONDS UNITS)" FORMAT = "A5" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN END_OBJECT = TABLE END 6.3.7.4 XSM Operating Parameters (S1_DCIXS_R00953_T8B.LBL) PDS_VERSION_ID = PDS3 /* FILE CHARACTERISTICS AND DATA ELEMENTS */ FILE_NAME = "S1_DCIXS_R00953_T8B.TAB" RECORD_TYPE = FIXED_LENGTH RECORD_BYTES = 121 FILE_RECORDS = 35 INTERCHANGE_FORMAT = ASCII /* DATA OBJECT POINTERS */ ^TABLE = ("S1_DCIXS_R00953_T8B.TAB",1) /* IDENTIFICATION DATA ELEMENTS */ DATA_SET_ID = "S1-L-DCIXS-2-EDR-LP-V1.0" DATA_SET_NAME = "SMART-1 DCIXS LEVEL 2 EDR LUNAR DATA V1.0" PRODUCT_ID = "S1_DCIXS_R00953_T8B" PRODUCT_CREATION_TIME = 2009-08-18T15:15:19 PRODUCT_TYPE = EDR PRODUCER_ID = DCIXS_TEAM PRODUCER_INSTITUTION_NAME = "RUTHERFORD APPLETON LABORATORY" PRODUCER_FULL_NAME = "ANDREW MCDERMOTT" PROCESSING_LEVEL_ID = 2 PROCESSING_LEVEL_DESC = "EDITED DATA CORRECTED FOR TELEMETRY ERRORS" DATA_QUALITY_ID = 1 DATA_QUALITY_DESC = "1=NORMAL 2=POOR" MISSION_ID = SMART1 MISSION_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" MISSION_PHASE_NAME = "LUNAR PHASE" INSTRUMENT_HOST_ID = S1 INSTRUMENT_HOST_NAME = "SMALL MISSIONS FOR ADVANCED RESEARCH AND TECHNOLOGY" INSTRUMENT_ID = DCIXS INSTRUMENT_NAME = "DEMONSTRATION OF A COMPACT IMAGING X-RAY SPECTROMETER" INSTRUMENT_TYPE = "SPECTROMETER" INSTRUMENT_MODE_ID = OPERATING INSTRUMENT_MODE_DESC = "OPERATING" TARGET_NAME = "MOON" TARGET_TYPE = "SATELLITE" START_TIME = 2005-07-26T22:30:28 STOP_TIME = 2005-07-27T00:55:52 SPACECRAFT_CLOCK_START_COUNT = "8/44701746.33728" SPACECRAFT_CLOCK_STOP_COUNT = "8/44709026.32320" ORBIT_NUMBER = 953 /* POSITIONAL INFORMATION */ RIGHT_ASCENSION = 253.072 DECLINATION = 56.271 WESTERNMOST_LONGITUDE = -140.047 EASTERNMOST_LONGITUDE = 46.952 MINIMUM_LATITUDE = -70.653 MAXIMUM_LATITUDE = 76.212 INCIDENCE_ANGLE = -1.000 PHASE_ANGLE = 91.287 EMISSION_ANGLE = 8.473 LOCAL_HOUR_ANGLE = 100.143 SUB_SPACECRAFT_LONGITUDE = 43.467 SUB_SPACECRAFT_LATITUDE = 81.330 SPACECRAFT_ALTITUDE = 2778.137 NOTE = "THIS DATA PRODUCT HAS BEEN GENERATED BY THE GDP SOFTWARE. CONFIGURATION FILES USED: SM1_DCIXS_1006_T08_AUX.tcf SM1_DCIXS_1006_T8B_AUX.dcf SM1_DCIXS_1006_T8B_AUX.pcf SPICE KERNELS USED: NAIF0009.TLS PCK00008.TPC MOON_PA_DE418_1950-2050.BPC MOON_071218.TF MOON_ASSOC_ME.TF EARTH_TOPO_050714.TF RSSD0002.TF DE418.BSP SMART1_070227_STEP.TSC ATNS_P030929010023_00188.BC ATNS_P050930150947_00220.BC ATNS_P060301004212_00233.BC EARTHSTNS_FX_050714.BSP EARTHSTNS_ITRF93_050714.BSP ORES_______________00125.BSP ORMS_______________00233.BSP ORMS__041111020517_00206.BSP SMART1_STRUCT_V01.BSP SMART1_V11.TF SMART1_DCIXS_V03.TI " /* DATA OBJECTS DEFINITION */ OBJECT = TABLE INTERCHANGE_FORMAT = ASCII ROWS = 35 ROW_BYTES = 121 COLUMNS = 16 NAME = "XSM OPERATING PARAMETERS" DESCRIPTION = "XSM OPERATING PARAMETERS IN ENGINEERING UNITS" OBJECT = COLUMN NAME = "UTC_TIME" COLUMN_NUMBER = 1 BYTES = 23 DATA_TYPE = TIME START_BYTE = 1 DESCRIPTION = "START TIME OF MEASUREMENT (UTC)" FORMAT = "A23" UNIT = "UT" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_PELTIER_DAC" COLUMN_NUMBER = 2 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 25 DESCRIPTION = "XSM DEFAULT PELTIER TARGET TEMPR DAC O/P" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_DATA_THRSHLD" COLUMN_NUMBER = 3 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 31 DESCRIPTION = "XSM DEFAULT DISCRIMINATOR THRESHOLD" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_HVBIAS_OFFTEMP" COLUMN_NUMBER = 4 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 37 DESCRIPTION = "XSM MAX. DETECTOR TEMPERATURE TO KEEP HV BIAS ON" FORMAT = "F5.1" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_PKTGEN_THRSHLD" COLUMN_NUMBER = 5 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 43 DESCRIPTION = "XSM TOTAL COUNT THRESHOLD FOR SPECTRUM TRANSMISSION" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_DELTA_I" COLUMN_NUMBER = 6 BYTES = 7 DATA_TYPE = ASCII_REAL START_BYTE = 49 DESCRIPTION = "XSM DELTA LEAKAGE CURRENT THRESHOLD TO SHUT SHUTTER (pA = COUNT * 0.78125)" FORMAT = "F7.3" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_I" COLUMN_NUMBER = 7 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 57 DESCRIPTION = "XSM MAX EXPECTED LEAKAGE CURRENT AT END OF CALIBRATION (pA = COUNT * 0.78125)" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_I_SETTLE" COLUMN_NUMBER = 8 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 63 DESCRIPTION = "XSM LEAKAGE CURRENT SETTLING TIME IN SECONDS" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_SHTR_PULSES" COLUMN_NUMBER = 9 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 69 DESCRIPTION = "XSM NUMBER SHUTTER PULSES FOR AUTONOMOUS ACTIVATION" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_HVBIAS_ONTEMP" COLUMN_NUMBER = 10 BYTES = 5 DATA_TYPE = ASCII_REAL START_BYTE = 75 DESCRIPTION = "XSM MAX SAFE PIN TEMPERATURE FOR BIAS SWITCH-ON" FORMAT = "F5.1" UNIT = "degC" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_CALTIME" COLUMN_NUMBER = 11 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 81 DESCRIPTION = "XSM CALIBRATION INTEGRATION TIME IN SECONDS" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_SHTR_TRIES" COLUMN_NUMBER = 12 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 87 DESCRIPTION = "XSM NUMBER OF TIMES TO TRY SHUTTER OPEN/CLOSE" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_NOANNEAL_I" COLUMN_NUMBER = 13 BYTES = 7 DATA_TYPE = ASCII_REAL START_BYTE = 93 DESCRIPTION = "DELTA LEAKAGE CURRENT IN NO ANNEALING CASE (pA = COUNT * 0.78125)" FORMAT = "F7.3" UNIT = "pA" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_CAL_DELTA_I" COLUMN_NUMBER = 14 BYTES = 7 DATA_TYPE = ASCII_REAL START_BYTE = 101 DESCRIPTION = "XSM MARGIN FOR EXCESS LEAKAGE CURRENT IN CALIBRATION (pA = COUNT * 0.78125)" FORMAT = "F7.3" UNIT = "pA" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_ANNEAL_TIME" COLUMN_NUMBER = 15 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 109 DESCRIPTION = "XSM ANNEALING PERIOD IN SECONDS" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN OBJECT = COLUMN NAME = "XSM_ANNEAL_I_SETTLE" COLUMN_NUMBER = 16 BYTES = 5 DATA_TYPE = ASCII_INTEGER START_BYTE = 115 DESCRIPTION = "XSM LEAKAGE CURRENT SETTLING TIME BEFORE ANNEALING" UNIT = "N/A" VALID_MAXIMUM = "N/A" VALID_MINIMUM = "N/A" END_OBJECT = COLUMN END_OBJECT = TABLE END