Dawn Radio Science Instrument Description Note: This document has been adapted (with minor editorial improvements and technical updates) from the INST.CAT files which accompanied the original PDS3 archive. It applies to both Vesta and Ceres encounters. Instrument Overview =================== The gravity science instrument utilized the deep space transponder onboard the Dawn spacecraft and Doppler tracking equipment at the Deep Space Network (DSN) to perform radio science investigations to determine the gravitational fields of Vesta and Ceres. The spacecraft part of the radio science instrument is described immediately below; that is followed by a description of the DSN (ground) part of the instrument. For more information about the Dawn mission and spacecraft, see Russell and Raymond (2011). Instrument Specifications - Spacecraft ====================================== Instrument Id : RSS Instrument Host Id : DAWN Pi Pds User Id : UNK Instrument Name : GRAVITY SCIENCE INSTRUMENT Instrument Type : RADIO SCIENCE Build Date : UNK Instrument Mass : UNK Instrument Length : UNK Instrument Width : UNK Instrument Height : UNK Instrument Manufacturer Name : UNK Instrument Overview - Spacecraft ================================ The Dawn telecommunications system used a Small Deep Space Transponder (SDST), which operated at X-band wavelength (3.6 cm). A ground station uplinked a carrier to the spacecraft which the Dawn receiver acquired and tracked. The spacecraft transmitted a signal that was coherent with the uplink signal but at a slightly higher frequency; this coherent mode was known as 'two-way'. When no uplink signal was present, the downlink signal was referenced to the onboard auxiliary oscillator ('one-way' mode). Occasionally one ground station transmitted while a different ground station received ('three-way' mode). Data that were noncoherent (one-way) contained too much Doppler noise to be useful for gravity science. Science Objectives ================== Analysis of interplanetary tracking data (both range data and VLBI) to Dawn can be used to improve the modeling of the orbits of Vesta and Ceres in future versions of solar system planetary ephemerides. The radio tracking data -- primarily Doppler, but also ranging -- from Vesta and Ceres orbital operations were used to improve knowledge of their respective gravity fields (see Konopliv et al., 2014, and Konopliv et al., 2018). Gravity Measurements -------------------- Measurement of the gravity field provides significant constraints on inferences about the interior structure of a body such as the mass distribution within an asteroid or dwarf planet. Studies of the gravity field emphasize both the global field and local characteristics of the field. The first task is to determine the global field. Doppler and range tracking measurements yield accurate spacecraft trajectory solutions. Simultaneously with reconstruction of the spacecraft orbit, observation equations for field coefficients and a small number of ancillary parameters can be solved. This type of gravity field solution is essential for characterizing tectonic phenomena and can also be used to study localized features. 'Short-arc' line-of-sight Doppler tracking measurements, obtained when the Earth-to-spacecraft line-of-sight is within a few degrees of the orbit plane, provide the highest resolution of local features. The results from this type of observation typically are presented as contoured acceleration profiles of specific features (e.g., craters or volcanoes) or line-of-sight acceleration maps of specific regions. The specifics of the gravity investigations at Vesta and Ceres are discussed by Konopliv et al. (2011). Operational Considerations - Spacecraft ======================================= The Dawn trajectory started being sensitive to Vesta and Ceres on approach. Coverage in the archive is shown below: First Radio Tracking Data Last Radio Tracking Data Vesta 2011-07-10 2012-09-05 Ceres 2015-01-02 2016-09-06 Spacecraft tracking was typically performed in coherent (two-way or three-way mode) once per day. Dawn's mission profile was unique due to the use of electric ion engines, which provided the main source of propulsion for the spacecraft. Instead of impulsive maneuvers provided by chemical rockets that change the orbit of the spacecraft quickly, ion engines provide long periods of continuous low thrust. During these periods, gravity science data were not acquired. The spacecraft periodically performed angular momentum desaturation maneuvers. These maneuvers allowed the reaction wheels to spin down to avoid damage, but they had be countered by the use of thrusters. The details of each of these maneuvers are specified in the Small Forces Files (SFFs) of the Dawn Radio Science (RS) Raw Data Archive (RDA). At Vesta, the mission was divided into three science orbits, all of which were polar. The Survey orbit was performed at a nominal altitude of 2735 km. The High Altitude Mapping Orbit (HAMO) was performed at a nominal altitude of 685 km. The Low Altitude Mapping Orbit (LAMO) was performed at a nominal altitude of 200 km. The spacecraft spent 20 days in Survey orbit, 34 days in HAMO-1, 141 days in LAMO, and another 40 days in HAMO-2. At Ceres, the mission was also divided into different science orbits, all of which were also polar. The RC3 orbit was conducted at an altitude of 13500 km, the Survey orbit was performed at a nominal altitude of 4400 km. The HAMO was performed at a nominal altitude of 1450 km, and the LAMO was performed at a nominal altitude of 375 km. An extended mission phase XMO1 was conducted at the same altitude as LAMO. Additional extended mission phases of XMO2, XMO3, and XMO4 were conducted at altitudes of 1480 km, 7520-9350 km, and 20000 km, respectively. Between pairs of science orbits, the spacecraft was in a transfer phase using the electric ion engines (Russell and Raymond, 2011). On rare occasions the spacecraft entered safe mode to protect itself from anomalous circumstances. During these times data may not have been collected for gravity science. At Vesta, Dawn entered safe mode on September 21, 2011, December 3, 2011, January 13, 2012, and February 21, 2012. At Ceres Dawn entered safe mode on June 30, 2015. Antenna Locations - Spacecraft =========================================== Four antennas were mounted on the Dawn spacecraft - three low gain antennas (LGAs) and one high gain antenna (HGA). The LGAs provided adequate signal-to-noise ratio (SNR) for gravity science (Konopliv et al., 2011). The phase centers of the antennas relative to the origin of the spacecraft-fixed frame were: Body ID X (meters) Y (meters) Z (meters) --------- ----------- ------------ ------------- PLUS_X_HGA 1.22 0.00 1.58 PLUS_X_LGA 0.99 0.45 0.33 PLUS_Z_LGA 0.26 -0.43 2.29 MINUS_Z_LGA 0.45 0.45 -0.01 Antenna Phase Center (APC) files in the Dawn RS RDA record times when LGAs were used. Otherwise the HGA was used. Investigators ============= Gravity science investigators were Alexander S. Konopliv Jet Propulsion Laboratory (M/S 301-121) 4800 Oak Grove Drive Pasadena, CA 91109-8099 1-818-354-6105 alexander.s.konopliv@jpl.nasa.gov Sami W. Asmar Jet Propulsion Laboratory (M/S 301-450) 4800 Oak Grove Drive Pasadena, CA 91109-8099 1-818-354-6288 sami.w.asmar@jpl.nasa.gov Ryan S. Park Jet Propulsion Laboratory (M/S 301-121) 4800 Oak Grove Drive Pasadena, CA 91109-8099 1-818-354-4401 ryan.s.park@jpl.nasa.gov Responsibility for creating the PDS3 archive was with Dustin R. Boccino Jet Propulsion Laboratory (M/S 230-215) 4800 Oak Grove Drive Pasadena, CA 91109-8099 1-818-393-9282 dustin.r.boccino@jpl.nasa.gov Instrument Overview - DSN ========================= Three Deep Space Communications Complexes (DSCCs) (near Barstow, CA; Canberra, Australia; and Madrid, Spain) comprise the DSN tracking network. Each complex is equipped with several antennas [including, during the Dawn era, at least one each 70-m, 34-m High Efficiency (HEF), and 34-m Beam WaveGuide (BWG)], associated electronics, and operational systems. Primary activity at each complex is radiation of commands to, and reception of telemetry data from, active spacecraft. Transmission and reception is possible in several radio-frequency bands including S-band (nominally a frequency of 2100-2300 MHz or a wavelength of 14.2-13.0 cm) and X-band (7100-8500 MHz or 4.2-3.5 cm). Transmitter output powers of up to 400 kW are available. Ground stations have the ability to transmit coded and uncoded waveforms which can be echoed by distant spacecraft. Analysis of the received coding allows navigators to determine the distance to the spacecraft; analysis of Doppler shift on the carrier signal allows estimation of the line-of-sight spacecraft velocity. Range and Doppler measurements are used to calculate the spacecraft trajectory and to infer gravity fields of objects near the spacecraft. Ground stations can record spacecraft signals that have propagated through, or been scattered from, target media. Measurements of signal parameters after wave interactions with surfaces, atmospheres, rings, and plasmas are used to infer physical and electrical properties of the target. Principal investigators vary from experiment to experiment. See the corresponding section of the spacecraft instrument description (above) or the archive description for specific information on Dawn gravity science investigators. The Deep Space Network is managed by the Jet Propulsion Laboratory of the California Institute of Technology for the U. S. National Aeronautics and Space Administration (NASA). Specifications include: Instrument Id : RSS Instrument Host Id : DSN Pi Pds User Id : N/A Instrument Name : RADIO SCIENCE SUBSYSTEM Instrument Type : RADIO SCIENCE Build Date : N/A Instrument Mass : N/A Instrument Length : N/A Instrument Width : N/A Instrument Height : N/A Instrument Manufacturer Name : N/A For more information on the Deep Space Network and its use in radio science see reports by Asmar and Renzetti (1993) and by Asmar et al. (1995). For design specifications on DSN subsystems in the Dawn era see a version of the Deep Space Network Telecommunications Link Design Handbook that would have been applicable in the 2010-2016 time frame. Subsystems - DSN ================ The Deep Space Communications Complexes (DSCCs) are an integral part of Radio Science instrumentation, along with the spacecraft Radio Frequency Subsystem. Their system performance directly determines the degree of success of Radio Science investigations, and their system calibration determines the degree of accuracy in the results of the experiments. The following paragraphs describe the functions performed by the individual subsystems of a DSCC. This material has been adapted from Asmar et al. (1995) and DSN 820-013 (JPL D-16765); for additional information, consult DSN 810-005. Each DSCC includes a set of antennas, a Signal Processing Center (SPC), and communication links to the Jet Propulsion Laboratory (JPL). The general configuration is illustrated below; antennas (Deep Space Stations, or DSS -- a term carried over from earlier times when antennas were individually instrumented) are listed in the table which follows. -------- -------- -------- -------- -------- | DSS 25 | | DSS 27 | | DSS 14 | | DSS 15 | | DSS 16 | |34-m BWG| |34-m HSB| | 70-m | |34-m HEF| | 26-m | -------- -------- -------- -------- -------- | | | | | | v v | v | --------- | --------- --------->|GOLDSTONE|<---------- |EARTH/ORB| | SPC 10 |<-------------->| LINK | --------- --------- | SPC |<-------------->| 26-M | | COMM | ------>| COMM | --------- | --------- | | | v | v ------ --------- | --------- | NOCC |<--->| JPL |<------- | | ------ | CENTRAL | | GSFC | ------ | COMM | | NASCOMM | | MCCC |<--->| TERMINAL|<-------------->| | ------ --------- --------- ^ ^ | | CANBERRA (SPC 40) <---------------- | | MADRID (SPC 60) <---------------------- GOLDSTONE CANBERRA MADRID Antenna SPC 10 SPC 40 SPC 60 -------- --------- -------- -------- 26-m DSS 16 DSS 46 DSS 66 34-m HEF DSS 15 DSS 45 DSS 65 34-m BWG DSS 24 DSS 34 DSS 54 DSS 25 DSS 26 34-m HSB DSS 27 DSS 28 70-m DSS 14 DSS 43 DSS 63 Developmental DSS 13 Subsystem interconnections at each DSCC are shown in the diagram below, and they are described in the sections that follow. The Monitor and Control Subsystem is connected to all other subsystems; the Test Support Subsystem can be. ----------- ------------------ --------- --------- |TRANSMITTER| | | | TRACKING| | COMMAND | | SUBSYSTEM |-| RECEIVER/EXCITER |-|SUBSYSTEM|-|SUBSYSTEM|- ----------- | | --------- --------- | | | SUBSYSTEM | | | | ----------- | | --------------------- | | MICROWAVE | | | | TELEMETRY | | | SUBSYSTEM |-| |-| SUBSYSTEM |- ----------- ------------------ --------------------- | | | ----------- ----------- --------- -------------- | | ANTENNA | | MONITOR | | TEST | | DIGITAL | | | SUBSYSTEM | |AND CONTROL| | SUPPORT | |COMMUNICATIONS|- ----------- | SUBSYSTEM | |SUBSYSTEM| | SUBSYSTEM | ----------- --------- -------------- DSCC Monitor and Control Subsystem ---------------------------------- The DSCC Monitor and Control Subsystem (DMC) is part of the Monitor and Control System (MON) which also includes the ground communications Central Communications Terminal and the Network Operations Control Center (NOCC) Monitor and Control Subsystem. The DMC is the center of activity at a DSCC. The DMC receives and archives most of the information from the NOCC needed by the various DSCC subsystems during their operation. Control of most of the DSCC subsystems, as well as the handling and displaying of any responses to control directives and configuration and status information received from each of the subsystems, is done through the DMC. The effect of this is to centralize the control, display, and archiving functions necessary to operate a DSCC. Communication among the various subsystems is done using a Local Area Network (LAN) hooked up to each subsystem via a network interface unit (NIU). DSCC Antenna Mechanical Subsystem --------------------------------- Multi-mission Radio Science activities require support from the 70-m, 34-m HEF, and 34-m BWG antenna subnets. The antennas at each DSCC function as large-aperture collectors which, by double reflection, cause the incoming radio frequency (RF) energy to enter the feed horns. The large collecting surface of the antenna focuses the incoming energy onto a subreflector, which is adjustable in both axial and angular position. These adjustments are made to correct for gravitational deformation of the antenna as it moves between zenith and the horizon; the deformation can be as large as 5 cm. The subreflector adjustments optimize the channeling of energy from the primary reflector to the subreflector and then to the feed horns. The 70-m and 34-m HEF antennas have 'shaped' primary and secondary reflectors, with forms that are modified paraboloids. This customization allows more uniform illumination of one reflector by another. The BWG reflector shape is ellipsoidal. On the 70-m antennas, the subreflector directs received energy from the antenna onto a dichroic plate, a device which reflects S-band energy to the S-band feed horn and passes X-band energy through to the X-band feed horn. In the 34-m HEF, there is one 'common aperture feed,' which accepts both frequencies without requiring a dichroic plate. In the 34-m BWG, a series of small mirrors (approximately 2.5 meters in diameter) directs microwave energy from the subreflector region to a collection area at the base of the antenna -- typically in a pedestal room. A retractable dichroic reflector separates S- and X-band on some BWG antennas or X- and Ka-band on others. RF energy to be transmitted into space by the horns is focused by the reflectors into narrow cylindrical beams, pointed with high precision (either to the dichroic plate or directly to the subreflector) by a series of drive motors and gear trains that can rotate the movable components and their support structures. The different antennas can be pointed by several means. Two pointing modes commonly used during tracking passes are CONSCAN and 'blind pointing.' With CONSCAN enabled and a closed loop receiver locked to a spacecraft signal, the system tracks the radio source by conically scanning around its position in the sky. Pointing angle adjustments are computed from signal strength information (feedback) supplied by the receiver. In this mode the Antenna Pointing Assembly (APA) generates a circular scan pattern which is sent to the Antenna Control System (ACS). The ACS adds the scan pattern to the corrected pointing angle predicts. Software in the receiver-exciter controller computes the received signal level and sends it to the APA. The correlation of scan position with the received signal level variations allows the APA to compute offset changes which are sent to the ACS. Thus, within the capability of the closed-loop control system, the scan center is pointed precisely at the apparent direction of the spacecraft signal source. An additional function of the APA is to provide antenna position angles and residuals, antenna control mode/status information, and predict-correction parameters to the Area Routing Assembly (ARA) via the LAN, which then sends this information to JPL via the Ground Communications Facility (GCF) for antenna status monitoring. During periods when excessive signal level dynamics or low received signal levels are expected (e.g., during an occultation experiment), CONSCAN should not be used. Under these conditions, blind pointing (CONSCAN OFF) is used, and pointing angle adjustments are based on a predetermined Systematic Error Correction (SEC) model. Independent of CONSCAN state, subreflector motion in at least the z-axis may introduce phase variations into the received Radio Science data. For that reason, during certain experiments, the subreflector in the 70-m and 34-m HEFs may be frozen in the z-axis at a position (often based on elevation angle) selected to minimize phase change and signal degradation. This can be done via Operator Control Inputs (OCIs) from the LMC to the Subreflector Controller (SRC) which resides in the alidade room of the antennas. The SRC passes the commands to motors that drive the subreflector to the desired position. Pointing angles for all antenna types are computed by the NOCC Support System (NSS) from an ephemeris provided by the flight project. These predicts are received and archived by the CMC. Before each track, they are transferred to the APA, which transforms the direction cosines of the predicts into AZ-EL coordinates. The LMC operator then downloads the antenna predict points to the antenna-mounted ACS computer along with a selected SEC model. The pointing predicts consist of time-tagged AZ-EL points at selected time intervals along with polynomial coefficients for interpolation between points. The ACS automatically interpolates the predict points, corrects the pointing predicts for refraction and subreflector position, and adds the proper systematic error correction and any manually entered antenna offsets. The ACS then sends angular position commands for each axis at the rate of one per second. In the 70-m and 34-m HEF, rate commands are generated from the position commands at the servo controller and are subsequently used to steer the antenna. When not using binary predicts (the routine mode for spacecraft tracking), the antennas can be pointed using 'planetary mode' -- a simpler mode which uses right ascension (RA) and declination (DEC) values. These change very slowly with respect to the celestial frame. Values are provided to the station in text form for manual entry. The ACS quadratically interpolates among three RA and DEC points which are on one-day centers. A third pointing mode -- sidereal -- is available for tracking radio sources fixed with respect to the celestial frame. Regardless of the pointing mode being used, a 70-m antenna has a special high-accuracy pointing capability called 'precision' mode. A pointing control loop derives the main AZ-EL pointing servo drive error signals from a two- axis autocollimator mounted on the Intermediate Reference Structure. The autocollimator projects a light beam to a precision mirror mounted on the Master Equatorial drive system, a much smaller structure, independent of the main antenna, which is exactly positioned in HA and DEC with shaft encoders. The autocollimator detects elevation/cross- elevation errors between the two reference surfaces by measuring the angular displacement of the reflected light beam. This error is compensated for in the antenna servo by moving the antenna in the appropriate AZ-EL direction. Pointing accuracies of 0.004 degrees (15 arc seconds) are possible in 'precision' mode. The 'precision' mode is not available on 34-m antennas -- nor is it needed, since their beamwidths are twice as large as on the 70-m antennas. DSCC Antenna Microwave Subsystem -------------------------------- 70-m Antennas: Each 70-m antenna has three feed cones installed in a structure at the center of the main reflector. The feeds are positioned 120 degrees apart on a circle. Selection of the feed is made by rotation of the subreflector. A dichroic mirror assembly, half on the S-band cone and half on the X-band cone, permits simultaneous use of the S- and X-band frequencies. The third cone is devoted to R&D and more specialized work. The Antenna Microwave Subsystem (AMS) accepts the received S- and X-band signals at the feed horn and transmits them through polarizer plates to an orthomode transducer. The polarizer plates are adjusted so that the signals are directed to a pair of redundant amplifiers for each frequency, thus allowing simultaneous reception of signals in two orthogonal polarizations. For S-band these are two Block IVA S-band Traveling Wave Masers (TWMs); for X-band the amplifiers are Block IIA TWMs. 34-m HEF Antennas: The 34-m HEF uses a single feed for both S- and X-band. Simultaneous S- and X-band receive as well as X-band transmit is possible thanks to the presence of an S/X 'combiner' which acts as a diplexer. For S-band, RCP or LCP is user selected through a switch so neither a polarizer nor an orthomode transducer is needed. X-band amplification options include two Block II TWMs or an HEMT Low Noise Amplifier (LNA). S-band amplification is provided by an FET LNA. 34-m BWG Antennas: These antennas use feeds and low-noise amplifiers (LNA) in the pedestal room, which can be switched in and out as needed. Typically the following modes are available: 1. downlink non-diplexed path (RCP or LCP) to LNA-1, with uplink in the opposite circular polarization; 2. downlink non-diplexed path (RCP or LCP) to LNA-2, with uplink in the opposite circular polarization 3. downlink diplexed path (RCP or LCP) to LNA-1, with uplink in the same circular polarization 4. downlink diplexed path (RCP or LCP) to LNA-2, with uplink in the same circular polarization For BWG antennas with dual-band capabilities (e.g., DSS 25) and dual LNAs, each of the above four modes can be used in a single-frequency or dual-frequency configuration. Thus, for antennas with the most complete capabilities, there are sixteen possible ways to receive at a single frequency (2 polarizations, 2 waveguide path choices, 2 LNAs, and 2 bands). DSCC Receiver-Exciter Subsystem ------------------------------- The Receiver-Exciter Subsystem is composed of two groups of equipment: the closed-loop receiver group and the open-loop receiver group. This subsystem is controlled by the Receiver-Exciter Controller (REC) which communicates directly with the DMC for predicts and OCI reception and status reporting. The exciter generates the S-band signal (or X-band for the 34-m HEF only) which is provided to the Transmitter Subsystem for the spacecraft uplink signal. It is tunable under command of the Digitally Controlled Oscillator (DCO) which receives predicts from the Metric Data Assembly (MDA). The diplexer in the signal path between the transmitter and the feed horn for all three antennas (used for simultaneous transmission and reception) may be configured such that it is out of the received signal path (in listen-only or bypass mode) in order to improve the signal-to-noise ratio in the receiver system. Closed Loop Receivers: The Block V receiver-exciter at the 70-m stations allows for two receiver channels, each capable of L-Band (e.g., 1668 MHz frequency or 18 cm wavelength), S-band, or X-band reception, and an S-band exciter for generation of uplink signals through the low-power or high-power transmitter. The closed-loop receivers provide the capability for rapid acquisition of a spacecraft signal and telemetry lockup. In order to accomplish acquisition within a short time, the receivers are predict driven to search for, acquire, and track the downlink automatically. Rapid acquisition precludes manual tuning though that remains as a backup capability. The subsystem utilizes FFT analyzers for rapid acquisition. The predicts are NSS generated, transmitted to the CMC which sends them to the Receiver-Exciter Subsystem where two sets can be stored. The receiver starts acquisition at uplink time plus one round-trip-light-time or at operator specified times. The receivers may also be operated from the LMC without a local operator attending them. The receivers send performance and status data, displays, and event messages to the LMC. Either the exciter synthesizer signal or the simulation (SIM) synthesizer signal is used as the reference for the Doppler extractor in the closed-loop receiver systems, depending on the spacecraft being tracked (and Project guidelines). The SIM synthesizer is not ramped; instead it uses one constant frequency, the Track Synthesizer Frequency (TSF), which is an average frequency for the entire pass. The closed-loop receiver AGC loop can be configured to one of three settings: narrow, medium, or wide. It will be configured such that the expected amplitude changes are accommodated with minimum distortion. The loop bandwidth (2BLo) will be configured such that the expected phase changes can be accommodated while maintaining the best possible loop SNR. Open-Loop Receivers (OLR): The OLR utilized a fixed first Local Oscillator (LO) frequency and a tunable second LO frequency to minimize phase noise and improve frequency stability. The OLR consisted of an RF-to-IF downconverter located at the feed , an IF selection switch (IFS), and a Radio Science Receiver (RSR). The RF-IF downconverters in the 70-m antennas were equipped for four IF channels: S-RCP, S-LCP, X-RCP, and X-LCP. The 34-m HEF stations were equipped with a two-channel RF-IF: S-band and X-band. The IFS switched the IF input among the antennas. DSCC Transmitter Subsystem -------------------------- The Transmitter Subsystem accepts the S-band frequency exciter signal from the Receiver-Exciter Subsystem exciter and amplifies it to the required transmit output level. The amplified signal is routed via the diplexer through the feed horn to the antenna and then focused and beamed to the spacecraft. The Transmitter Subsystem power capabilities range from 18 kW to 400 kW. Power levels above 18 kW are available only at 70-m stations. DSCC Tracking Subsystem ----------------------- The Tracking Subsystem primary functions are to acquire and maintain communications with the spacecraft and to generate and format radiometric data containing Doppler and range. The DSCC Tracking Subsystem (DTK) receives the carrier signals and ranging spectra from the Receiver-Exciter Subsystem. The Doppler cycle counts are counted, formatted, and transmitted to JPL in real time. Ranging data are also transmitted to JPL in real time. Also contained in these blocks is the AGC information from the Receiver-Exciter Subsystem. The Radio Metric Data Conditioning Team (RMDCT) at JPL produces a Tracking and Navigation Service File (TNF), which contains Doppler and ranging data. In addition, the Tracking Subsystem receives from the CMC frequency predicts (used to compute frequency residuals and noise estimates), receiver tuning predicts (used to tune the closed-loop receivers), and uplink tuning predicts (used to tune the exciter). From the LMC, it receives configuration and control directives as well as configuration and status information on the transmitter, microwave, and frequency and timing subsystems. The Metric Data Assembly (MDA) controls all of the DTK functions supporting the uplink and downlink activities. The MDA receives uplink predicts and controls the uplink tuning by commanding the DCO. The MDA also controls the Sequential Ranging Assembly (SRA). It formats the Doppler and range measurements and provides them to the GCF for transmission to NOCC. The Sequential Ranging Assembly (SRA) measures the round trip light time (RTLT) of a radio signal traveling from a ground tracking station to a spacecraft and back. From the RTLT, phase, and Doppler data, the spacecraft range can be determined. A coded signal is modulated on an uplink carrier and transmitted to the spacecraft where it is detected and transponded back to the ground station. As a result, the signal received at the tracking station is delayed by its round trip through space and shifted in frequency by the Doppler effect due to the relative motion between the spacecraft and the tracking station on Earth. DSCC Frequency and Timing Subsystem ----------------------------------- The Frequency and Timing Subsystem (FTS) provides all frequency and timing references required by the other DSCC subsystems. It contains four frequency standards of which one is prime and the other three are backups. Selection of the prime standard is done via the CMC. Of these four standards, two are hydrogen masers followed by clean-up loops (CUL) and two are cesium standards. These four standards all feed the Coherent Reference Generator (CRG) which provides the frequency references used by the rest of the complex. It also provides the frequency reference to the Master Clock Assembly (MCA) which in turn provides time to the Time Insertion and Distribution Assembly (TID) which provides UTC and SIM-time to the complex. JPL's ability to monitor the FTS at each DSCC is limited to the MDA calculated Doppler pseudo-residuals, the Doppler noise, the SSI, and to a system which uses the Global Positioning System (GPS). GPS receivers at each DSCC receive a one-pulse-per-second pulse from the station's (hydrogen maser referenced) FTS and a pulse from a GPS satellite at scheduled times. After compensating for the satellite signal delay, the timing offset is reported to JPL where a database is kept. The clock offsets stored in the JPL database are given in microseconds; each entry is a mean reading of measurements from several GPS satellites and a time tag associated with the mean reading. The clock offsets provided include those of SPC 10 relative to UTC (NIST), SPC 40 relative to SPC 10, etc. Detectors - DSN =============== Nominal carrier tracking loop threshold noise bandwidth at X-band is 10 Hz. Coherent (two-way) closed-loop system stability is shown in the table below: integration time Doppler uncertainty (secs) (one sigma, microns/sec) ------ ------------------------ 10 50 60 20 1000 4 For the open-loop subsystem, signal detection is done in software. Calibration - DSN ================= Calibrations of hardware systems are carried out periodically by DSN personnel; these ensure that systems operate at required performance levels -- for example, that antenna patterns, receiver gain, propagation delays, and Doppler uncertainties meet specifications. No information on specific calibration activities is available. Nominal performance specifications are shown in the tables above. Additional information may be available in [DSN810-5]. Prior to each tracking pass, station operators perform a series of calibrations to ensure that systems meet specifications for that operational period. Included in these calibrations is measurement of receiver system temperature in the configuration to be employed during the pass. Results of these calibrations are recorded in (hard copy) Controller's Logs for each pass. The nominal procedure for initializing open-loop receiver attenuator settings is described below. In cases where widely varying signal levels are expected, the procedure may be modified in advance or real-time adjustments may be made to attenuator settings. Operational Considerations - DSN ================================ The DSN is a complex and dynamic 'instrument.' Its performance for Radio Science depends on a number of factors from equipment configuration to meteorological conditions. No specific information on 'operational considerations' can be given here. Operational Modes - DSN ======================= DSCC Antenna Mechanical Subsystem --------------------------------- Pointing of DSCC antennas may be carried out in several ways. For details see the subsection 'DSCC Antenna Mechanical Subsystem' in the 'Subsystem' section. Binary pointing is the preferred mode for tracking spacecraft; pointing predicts are provided, and the antenna simply follows those. With CONSCAN, the antenna scans conically about the optimum pointing direction, using closed-loop receiver signal strength estimates as feedback. In planetary mode, the system interpolates from three (slowly changing) RA-DEC target coordinates; this is 'blind' pointing since there is no feedback from a detected signal. In sidereal mode, the antenna tracks a fixed point on the celestial sphere. In 'precision' mode, the antenna pointing is adjusted using an optical feedback system. It is possible on most antennas to freeze z-axis motion of the subreflector to minimize phase changes in the received signal. DSCC Receiver-Exciter Subsystem ------------------------------- The diplexer in the signal path between the transmitter and the feed horns on all antennas may be configured so that it is out of the received signal path in order to improve the signal-to-noise ratio in the receiver system. This is known as the 'listen-only' or 'bypass' mode. Closed-Loop Receiver AGC Loop ----------------------------- The closed-loop receiver AGC loop can be configured to one of three settings: narrow, medium, or wide. Ordinarily it is configured so that expected signal amplitude changes are accommodated with minimum distortion. The loop bandwidth is ordinarily configured so that expected phase changes can be accommodated while maintaining the best possible loop SNR. Coherent vs. Non-Coherent Operation ----------------------------------- The frequency of the signal transmitted from the spacecraft can generally be controlled in two ways -- by locking to a signal received from a ground station or by locking to an on-board oscillator. These are known as the coherent (or 'two-way') and non-coherent ('one-way') modes, respectively. Mode selection is made at the spacecraft, based on commands received from the ground. When operating in the coherent mode, the transponder carrier frequency is derived from the received uplink carrier frequency with a 'turn-around ratio' typically of 880/749. In the non-coherent mode, the downlink carrier frequency is derived from the spacecraft on-board crystal-controlled oscillator. Either closed-loop or open-loop receivers (or both) can be used with either spacecraft frequency reference mode. Closed-loop reception in two-way mode is usually preferred for routine tracking. Occasionally the spacecraft operates coherently while two ground stations receive the 'downlink' signal; this is sometimes known as the 'three-way' mode. Location - DSN ============== Station locations are documented in DSN 810-005 (see especially modsule 301). Geocentric coordinates are summarized here. Geocentric Geocentric Geocentric Station Radius (km) Latitude (N) Longitude (E) ------------------- ------------ ------------ ------------- Goldstone DSS 13 (34-m R&D) 6372125.096 35.0660180 243.2055410 DSS 14 (70-m) 6371993.267 35.2443523 243.1104618 DSS 15 (34-m HEF) 6371966.511 35.2403129 243.1128049 DSS 24 (34-m BWG) 6371973.601 35.1585346 243.1252056 DSS 25 (34-m BWG) 6371982.537 35.1562591 243.1246368 DSS 26 (34-m BWG) 6371992.264 35.1543409 243.1269835 Canberra DSS 34 (34-m BWG) 6371693.538 -35.2169824 148.9819644 DSS 35 (34-m BWG) 6371697.350 -35.2143052 148.9814558 DSS 43 (70-m) 6371688.998 -35.2209189 148.9812673 DSS 45 (34-m HEF) 6371675.873 -35.2169608 148.9776856 Madrid DSS 54 (34-m BWG) 6370025.490 40.2357726 355.7459032 DSS 55 (34-m BWG) 6370007.988 40.2344478 355.7473667 DSS 63 (70-m) 6370051.198 40.2413554 355.7519915 DSS 65 (34-m HEF) 6370021.709 40.2373555 355.7493011 Measurement Parameters - DSN ============================ Closed-loop data are recorded in Tracking and Navigation Service Files (TNFs), as well as certain other products such as the Orbit Data File (ODF). The TNFs are comprised of SFDUs that have variable-length, variable-format records with mixed typing (i.e., can contain ASCII, integer, and floating-point items in a single record). These files all contain entries that include measurements of Doppler, Range, and signal strength, along with status and uplink frequency information. ACRONYMS AND ABBREVIATIONS - DSN ================================ ACS Antenna Control System ADC Analog-to-Digital Converter AGC Automatic Gain Control AMS Antenna Microwave System APA Antenna Pointing Assembly ARA Area Routing Assembly ATDF Archival Tracking Data File AUX Auxiliary AZ Azimuth BPF Band Pass Filter bps bits per second BWG Beam WaveGuide (antenna) CDU Command Detector Unit CMC Complex Monitor and Control CONSCAN Conical Scanning (antenna pointing mode) CRG Coherent Reference Generator CUL Clean-up Loop DANA a type of frequency synthesizer dB deciBel dBi dB relative to isotropic dBm dB relative to one milliwatt DCO Digitally Controlled Oscillator DDC Digital Down Converter DEC Declination deg degree DIG RSR Digitizer DMC DSCC Monitor and Control Subsystem DOR Differential One-way Ranging DP Data Processor DSCC Deep Space Communications Complex DSN Deep Space Network DSP DSCC Spectrum Processing Subsystem DSS Deep Space Station DTK DSCC Tracking Subsystem E east EIRP Effective Isotropic Radiated Power EL Elevation FET Field Effect Transistor FFT Fast Fourier Transform FIR Finite impulse Response FTS Frequency and Timing Subsystem GCF Ground Communications Facility GHz Gigahertz GPS Global Positioning System HA Hour Angle HEF High-Efficiency (as in 34-m HEF antennas) HEMT High Electron Mobility Transistor (amplifier) HGA High-Gain Antenna HSB High-Speed BWG IF Intermediate Frequency IFS IF Selector Switch IVC IF Selection Switch JPL Jet Propulsion Laboratory K Kelvin Ka-Band approximately 32 GHz KaBLE Ka-Band Link Experiment kbps kilobits per second kHz kilohertz km kilometer kW kilowatt LAN Local Area Network LCP Left-Circularly Polarized LGR Low-Gain Receive (antenna) LGT Low-Gain Transmit (antenna) LMA Lockheed Martin Astronautics LMC Link Monitor and Control LNA Low-Noise Amplifier LO Local Oscillator LPF Low Pass Filter m meters MCA Master Clock Assembly MCCC Mission Control and Computing Center MDA Metric Data Assembly MHz Megahertz MON Monitor and Control System MSA Mission Support Area N north NAR Noise Adding Radiometer NBOC Narrow-Band Occultation Converter NCO Numerically Controlled Oscillator NIST SPC 10 time relative to UTC NIU Network Interface Unit NOCC Network Operations and Control System NRV NOCC Radio Science/VLBI Display Subsystem NSS NOCC Support System OCI Operator Control Input ODF Orbit Data File ODR Original Data Record ODS Original Data Stream OLR Open Loop Receiver OSC Oscillator PDS Planetary Data System POCA Programmable Oscillator Control Assembly PPM Precision Power Monitor RA Right Ascension REC Receiver-Exciter Controller RCP Right-Circularly Polarized RF Radio Frequency RIC RIV Controller RIV Radio Science IF-VF Converter Assembly RMDCT Radio Metric Data Conditioning Team RMS Root Mean Square RSR Radio Science Receiver RSS Radio Science Subsystem RT Real-Time (control computer) RTLT Round-Trip Light Time S-band approximately 2100-2300 MHz sec second SEC System Error Correction SIM Simulation SLE Signal Level Estimator SNR Signal-to-Noise Ratio SNT System Noise Temperature SOE Sequence of Events SPA Spectrum Processing Assembly SPC Signal Processing Center sps samples per second SRA Sequential Ranging Assembly SRC Sub-Reflector Controller SSI Spectral Signal Indicator TID Time Insertion and Distribution Assembly TLM Telemetry TNF Tracking and Navigation File TSF Tracking Synthesizer Frequency TWM Traveling Wave Maser TWNC Two-Way Non-Coherent TWTA Traveling Wave Tube Amplifier UNK unknown USO UltraStable Oscillator UTC Universal Coordinated Time VCO Voltage-Controlled Oscillator VDP VME Data Processor VF Video Frequency X-band approximately 7800-8500 MHz References: Asmar, S. W., R. G. Herrera, and T. Priest, Radio Science Handbook, JPL D-7938 Vol. 6, Jet Propulsion Laboratory, Pasadena, CA, 1995. Asmar, S. W., and N. A. Renzetti, The Deep Space Network as an Instrument for Radio Science Research, Jet Propulsion Laboratory Publication 80-93, Rev. 1, 1993. ---, Deep Space Network Telecommunications Link Design Handbook, DSN 810-005, Jet Propulsion Laboratory, Pasadena, CA. ---, Deep Space Mission System (DSMS) External Interface Specification (DSN 820-013, JPL D-16765), Jet Propulsion Laboratory, Pasadena, CA. Konopliv, A. S., Asmar, S. W., Bills, B. G., Mastrodemos, N., Park, R. S., Raymond, C. A., Smith, D. E., and M. T. Zuber, The Dawn Gravity Investigation at Vesta and Ceres, Space Science Reviews, 163, 461-486, 2011. Konopliv, A. S., S. W. Asmar, R. S. Park, B. G. Bills, F. Centinello, A. B. Chamberlin, A. Ermakov, R. W. Gaskell, N. Rambaux, C. A. Raymond, C. T. Russell, D. E. Smith, P. Tricarico, and M. T. Zuber, The Vesta gravity field, spin pole and rotation period, landmark positions, and ephemeris from the Dawn tracking and optical data, Icarus, 240, 103-117, 2014. Konopliv, A. S., R. S. Park, A. T. Vaughan, B. G. Bills, S. W. Asmar, A. I. Ermakov, N. Rambaux, C. A. Raymond, J. C. Castillo-Rogez, C. T. Russell, D. E. Smith, and M. T. Zuber, The Ceres gravity field, spin pole, rotation period and orbit from the Dawn radiometric tracking and optical data, Icarus, 299, 411-429, 2018. Russell, C. T., and C. A. Raymond, The Dawn Mission to Vesta and Ceres, Space Science Reviews, 163, 3-23, 2011.