PDS_VERSION_ID = PDS3 LABEL_REVISION_NOTE ="2010-07-12,Stefano Mottola, first release" RECORD_TYPE = STREAM OBJECT = INSTRUMENT INSTRUMENT_HOST_ID = "RL" INSTRUMENT_ID ="ROLIS" OBJECT = INSTRUMENT_INFORMATION INSTRUMENT_NAME ={"ROSETTA LANDER IMAGING SYSTEM - DESCENT AND CLOSEUP IMAGER"} INSTRUMENT_TYPE ="IMAGING CAMERA" INSTRUMENT_DESC = " Scientific Objectives and Experiment Overview ============================================= ROLIS is a miniature Charge Coupled Device (CCD) imager pointing downwards from the balcony of the Rosetta Lander. From here, ROLIS can observe about 30x30 cm of the nucleus surface below the Lander at a spatial sampling of 0.3mm/pixel. In order to illuminate the image field, ROLIS incorporates four independent arrays of light emitting diodes (LEDs) radiating through the visible and near-IR, in spectral bands centred at 470, 530, 640 and 870nm, with a Full Width Half Maximum of about 100nm. ROLIS will also operate during the descent phase, imaging the landing site and its vicinity shortly before touchdown. From images of the cometary surface ROLIS will seek to identify the possible presence of a dust mantle, refractory crust and exposed ice. If present, surface features such as pores, cracks and vents would be readily detected, as well as traces of erosion caused by sublimation, ice grains and carbonaceous aggregates larger than the ROLIS spatial resolution limits. Together, the descent sequence and the close-up images will reveal the surface features over a broad range of scale lengths, allowing an assessment of the surface's diversity. Multi-spectral imaging in four spectral channels will allow us to complement the spatial information with spectral information. Although the limited spectral range and resolution of ROLIS will not allow exact mineralogy to be extracted, the study of the spectral slope should allow a broad classification of the solid surface phases to be derived, distinguishing between carbonaceous, silicates and organic materials. Further, the analysis of colour ratios over a given field will provide information on the degree of soil heterogeneity at small scales. Operational Considerations ========================== The Rosetta Lander and its payload are designed to achieve the primary mission goals within 3 days of landing, which takes place when the comet is at a heliocentric distance of 3 AU, before the onset of major cometary activity. Rosetta will approach the comet in the year 2014 and will start its descent phase at the ending of 2014. Should an extended mission be possible, it will be of great interest to use ROLIS to search for signs of evolution of the surface features as the Churyumov-Gerasimenko (CG) approaches the Sun. The ROLIS camera is designed for operations at temperatures down to -150 deg C what makes it possible to operate on the comet between approximately 3.5 to 1.8 AU. The comparatively warm temperatures at 1.8 AU would not be a problem for ROLIS either. Imaging the borehole sides could reveal stratification and provide clues on the mechanical strength of the surface layer. This could be achieved by rotating the Lander around its axis by a few degrees. The detection and precise measurement of the surface features would be greatly facilitated by the acquisition of stereo pairs, also achieved by rotating the Lander. They would provide the additional information from the lone-of-sight dimension, making it easier to identify surface features visually and to quantify their dimensions. Calibration =========== Following calibration functions are applied to the ROLIS images at DLR : 1) Dark correction: Each image is corrected by subtracting a dark frame derived by ground or in-flight calibrations. 2) Flat filed correction: each image is corrected by applying calibration flat fields derived during ground calibration. 3) If possible, photometric cross-calibration with OSIRIS data Electronics =========== The Imaging Main Electronics (IME) is a facility device, developed under the co-responsibility of IWP/DLR and IAS, for both ROLIS and CIVA: they share a common interface with the Lander, for both the power subsystem and the Central Data Management System (CDMS). The ROLIS IME tasks include implementation of the commanding interface to the Lander, data acquisition from the ROLIS-D camera, local storage of the images, image processing and compression, recording of HK information and the data link to the Lander. In addition, it provides storage, commanding, and telemetry support for the CIVA instrument, which is interfaced through a dedicated digital signal processor board. The ROLIS-part of IME consists of the DPU- and the MM- (Mass Memory) boards. The DPU is based on a Harris RTX 2010 processor running at 10 MHz and programmed in FORTH. The ROLIS experiment S/W is stored in a 64-kByte EEPROM, which can be partially or completely uploaded during flight. The MM consists of 16 MBytes of static RAM which is used as buffer for images and temporary storage. The memory enables the storage of a maximum of 7 uncompressed images and several compressed images, which number depends on their compression ratio, and is allocated to both the ROLIS and CIVA experiments. To gain comprehensive information about the ROLIS-DPU here a few details: - Processor: Harris RTX-2010RH at 10 MHz - FPGA: Actel 1280 RH - 16 KByte PROM with Common DPU (ComDPU) Software - 64 KByte EEPROM with ROLIS Software - 256 KByte SRAM - 14 bit ADC for ROLIS and CIVA analogue HK - interface to CDMS (max. 32 kbps), Watchdog - 78 kbps serial DPU-DPU I/F to the CIVA part of IME - Extension bus for special experiment hardware. The following notes contain details about the ROLIS MM: - FPGA: Actel 54SX16 RT - 4x 32 Mbit SRAM cubes for images - Memory controller - High-speed serial I/F to the ROLIS-D (10 Mbits per second). Accommodation ============ The two main modules of ROLIS, the ROLIS-D camera and the on-board processor unit & Mass Memory as part of the IME are located on the Lander at different sites: The IME is located in the warm compartment of PHILAE in the Central Elelectronics Box (CEB-Z) , whereas ROLIS-D is situated on the Lander balcony. Both ROLIS constituents are connected via a cable. The ROLIS-D location on the 'instrument common working circle' allows it to inspect the sampling sites of the Lander's in situ analyzers before and after the drilling operation. Such inspection, achieved by rotating the Lander body, can provide an important contribution to the interpretation of the sample analysis, by placing these measurements into the context of the surface colours and morphology. Software ======== Two types of software are used: 1. ComDPU software (in the PROM) 2. ROLIS software (in the EEPROM). After power switch on first the ComDPU software will be copied into RAM and started from the RAM. Analogue for the ROLIS software: after starting the boot process the ROLIS software will be copied from the EEPROM into the RAM (overwriting the ComDPU software) and get started. Imaging Modes ============= ROLIS can be operated in 3 basic imaging modes: - SINGLE IMAGE MODE - DESCENT IMAGING RING-BUFFER-MODE - FULL-FRAME IMAGE STRIPE Measured Parameters =================== The basic product of ROLIS are images. The ROLIS-D optics project a square Field Of View of 57.7 deg x 57.7 deg onto the CCD. This gives a sampling of about 0,33mm/pixel at an object distance of 30cm. With the Infinity Lens (IFL) in the optical path, the objective is focused for objects at distances ranging from 1.4m to infinity. With it removed, the camera is focused at an object distance of 30cm with a depth of field of approximately (+10; -8) cm. " END_OBJECT = INSTRUMENT_INFORMATION OBJECT = INSTRUMENT_REFERENCE_INFO REFERENCE_KEY_ID ="MOTTOLAETAL2007" END_OBJECT = INSTRUMENT_REFERENCE_INFO END_OBJECT = INSTRUMENT END