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HiRISE

The High Resolution Imaging Science Experiment (HiRISE) is a sophisticated visible- and near-infrared-spectrum camera mounted on NASA's (MRO), launched in 2005 and inserted into Mars orbit in 2006, enabling detailed scientific imaging of the planet's surface at resolutions up to 25 centimeters per pixel. As the most powerful camera ever deployed to another world, HiRISE captures wide-swath images measuring 6 kilometers across and up to 60 kilometers long, utilizing 14 () detectors with time-delay integration to produce color and stereo views in , red, and near-infrared bands. Its primary objectives include characterizing potential landing sites for future missions, monitoring active geological and atmospheric processes such as avalanches, recurring slope lineae, and dust devils, and investigating Mars' geologic history through features like craters, channels, layered deposits, and polar ice caps. Developed by Corporation under the leadership of Alfred McEwen (now emeritus) at the University of Arizona's Lunar and Planetary Laboratory, with current Shane Byrne, HiRISE was selected as one of six instruments for MRO to address key questions in during the mission's two-year primary science phase starting in November 2006, though operations have extended well beyond. The instrument, weighing 65 kilograms and consuming about 60 watts of power, features a 0.5-meter with a 12-meter focal length, allowing it to resolve surface features as small as 1 meter from an orbital altitude of 255-320 kilometers. As of November 2025, HiRISE has generated over 99,000 images covering approximately 2.5% of Mars' surface (accounting for overlaps in targeted observations), including thousands of stereo pairs that enable the creation of digital elevation models with vertical precision better than 25 centimeters, supporting analyses of and landscape evolution. HiRISE's contributions extend to mission planning and discovery, having informed landing site selections for NASA's Phoenix lander (2008), Mars Science Laboratory (Curiosity rover, 2012), InSight (2018), and Perseverance rover (2021), while also documenting dynamic phenomena like seasonal gully activity, possible briny flows, and impact sites from new craters. The experiment's data, totaling over 12 terabytes during the primary phase alone, are publicly accessible through the Planetary Data System and the HiRISE website, fostering over 2,000 peer-reviewed publications on topics ranging from volcanism and hydrology to aeolian and periglacial processes. Despite hardware anomalies, including the failure of RED9 in 2011 and RED4 in July 2023 that disabled one of its red CCDs, reducing color imaging capacity, HiRISE continues to operate effectively, providing ongoing insights into Mars' geology and environment as of November 2025.

Background

Overview

The High Resolution Imaging Science Experiment (HiRISE) is a visible and near-infrared imaging system aboard NASA's (MRO), designed to capture detailed views of the Martian surface. As one of six scientific instruments on MRO, HiRISE has been conducting ongoing observations since 2006, providing high-resolution imagery that supports a wide range of investigations. Led by principal investigator Alfred S. McEwen at the University of Arizona's Lunar and Planetary Laboratory, HiRISE was constructed by The instrument, weighing 65 kg, launched aboard MRO on August 12, 2005, and achieved orbital insertion around Mars on March 10, 2006. HiRISE represents the highest-resolution camera ever sent to another , capable of achieving 0.3 m per spatial from its nominal 300 km orbital altitude, with a swath width of 6 km per image. This capability enables the detection of fine-scale geological features, such as small craters and layered deposits, far surpassing previous orbital imagers.

Historical Development

The High Resolution Imaging Science Experiment (HiRISE) originated from a submitted in by W. Alan Delamere and Alfred S. McEwen, as part of NASA's competitive selection process for instruments on the (MRO) mission. The emphasized the need for unprecedented high-resolution imaging to characterize landing sites, monitor surface changes, and support future Mars exploration, building on lessons from prior missions like . NASA selected HiRISE on November 9, 2001, from among 26 submissions in response to the Announcement of Opportunity for MRO science investigations, recognizing its potential to achieve 25–50 cm/pixel resolution for detailed surface analysis. Under the leadership of Alfred S. McEwen at the University of Arizona's Lunar and Planetary Laboratory, the project advanced to the development phase, with Corp. in , contracted to design and fabricate the instrument from 2002 to 2005. This timeline included iterative refinements, such as adjusting the design for the finalized MRO orbit of 255 × 320 km to optimize capabilities while accommodating the spacecraft's constraints. Following fabrication, HiRISE underwent integration with the MRO spacecraft, including rigorous testing to ensure compatibility with the orbiter's systems. During the seven-month cruise phase after launch, calibration activities were conducted to verify instrument performance, including imaging of the and the star cluster on September 8, 2005, for flat-field and point-spread function assessments, as well as star tracker alignments on October 6, 2005. Additional calibrations targeted the Jewel Box Cluster (NGC 4755) in December 2005 to refine focus and alignment under varying stellar conditions. These pre-arrival tests confirmed HiRISE's optical stability and data quality prior to Mars operations. HiRISE launched aboard MRO on August 12, 2005, from Air Force Station, , via an rocket, marking the beginning of a journey that covered approximately 480 million kilometers to reach Mars. The spacecraft achieved orbital insertion on March 10, 2006, activating HiRISE for initial operations shortly thereafter. The instrument captured its first test images of the Martian surface on March 23 and 25, 2006, from an altitude of about 2,500 km, demonstrating resolutions approaching 30 cm/pixel and revealing fine-scale features like layered deposits in the region. These early images were publicly released in late March 2006, initiating systematic surface mapping aligned with MRO's primary science phase starting in November 2006. Subsequent mission extensions have sustained HiRISE operations beyond the original two-year primary phase, with approvals through multiple senior reviews enabling continued imaging into . As of the 2025 Planetary Mission Senior Review, MRO—including HiRISE—remains active in its sixth extended , focusing on long-term monitoring of dynamic processes on Mars while supporting functions for surface assets. This longevity has allowed HiRISE to document initial surface changes, such as seasonal patterns and dust activity, establishing a baseline for ongoing observations.

Objectives and Role

Scientific Goals

The High Resolution Imaging Science Experiment (HiRISE) was designed to characterize diverse surface features of Mars at sub-meter , enabling detailed studies of the planet's geological history, including evidence of past , , and erosional processes. Core objectives focus on resolving small-scale landforms such as layered deposits, channels, and impact craters to reconstruct timelines of aqueous alteration, magmatic activity, and aeolian modification. By imaging approximately 1% of Mars' surface at resolutions better than 1.2 m/ during its primary science phase, HiRISE aims to provide a global context for localized observations from rovers, extrapolating site-specific findings to broader planetary scales. Specific goals include monitoring temporal changes on the surface, such as seasonal flows in recurring lineae, dust devil tracks, and streaks, to assess active geological and atmospheric dynamics over multiple Mars years through 2025 and beyond. HiRISE also supports the identification of safe landing sites for future missions by evaluating hazards like boulders and at the meter scale, while selecting scientifically valuable locations rich in hydrated minerals or volcanic constructs. These efforts extend to tracking polar CO₂ rates and mid-latitude formation to probe recent climate variability. The instrument's wavelength-specific aims leverage (400–600 nm), (550–850 nm), and near-infrared (800–1000 nm) bands across portions of its imaging swath to differentiate compositions, detect ices, and analyze atmospheric hazes, facilitating identification of phyllosilicates indicative of water-rock interactions and basaltic signatures of . With its 0.3 m/ capability, HiRISE enables these distinctions in targeted pairs for topographic mapping. Broader impacts encompass hypothesis testing for Mars' habitability potential through evidence of past hydrothermal systems and climate evolution via long-term monitoring of volatile cycles, contributing to a comprehensive understanding of the planet's environmental history.

Mission Support Functions

HiRISE has played a crucial role in landing site selection for multiple Mars missions by providing high-resolution images that assess surface hazards such as rocks and slopes, enabling safer landings. For the Phoenix lander, which arrived in 2008, HiRISE contributed to site certification through stereo imaging and digital terrain models (DTMs) that mapped rock distributions and topography at sub-meter scales. Similarly, for the Mars Science Laboratory (MSL) mission in 2012 and the InSight lander in 2018, HiRISE acquired over 650 images across these and other campaigns, identifying small-scale features to refine candidate sites and confirm low-risk zones. These efforts extended to the Mars 2020 Perseverance rover, where HiRISE data supported final site selection in Jezero Crater by evaluating geologic context and hazard avoidance. In supporting rover and lander operations, HiRISE conducts repeated imaging to monitor mobility, traverse paths, and environmental changes like dust accumulation. For instance, it has tracked the Opportunity rover's wheel tracks and location, aiding path planning to minimize damage. HiRISE similarly images the Curiosity rover, including a February 2025 observation capturing it mid-drive to assess progress and surface alterations, and monitors dust buildup on its solar panels and instruments. For Perseverance, HiRISE images document its traverses in Jezero Crater, supporting mobility assessments and dust devil activity around the site. The HiWish program integrates public engagement by allowing citizen scientists to suggest imaging targets, fostering broader participation in Mars exploration. Launched in early , the program has received 27,681 public suggestions as of April 2022, with 13,407 fulfilled through dedicated HiRISE observations. These requests often complement mission priorities, such as monitoring dynamic features or unexplored regions, and have resulted in diverse images that enhance scientific . HiRISE also fulfills roles, including post-landing confirmation and providing global context for in-situ measurements. A example is the imaging of Phoenix's descent on May 25, 2008, capturing the lander under parachute approximately 3 minutes before touchdown, which verified the entry, descent, and landing sequence. For ongoing missions, HiRISE supplies orbital context to interpret ground data from rovers like and , such as correlating local geology with broader crater features. Through inter-mission synergy, HiRISE data informs planning for sample collection and future human exploration. For Perseverance, high-resolution DTMs and images guide sample site selection by mapping potential astrobiological targets in Jezero Crater, ensuring strategic caching for return missions. Additionally, HiRISE has acquired 43 images requested by NASA and SpaceX since a 2015 human landing site workshop, providing hazard assessments and resource mapping as precursors to crewed operations.

Instrument Design

Optical and Hardware Specifications

The HiRISE instrument employs an all-reflective telescope design, featuring a 0.5-meter diameter primary mirror constructed from lightweight material. This represents the largest ever flown on an interplanetary , enabling high-resolution imaging from Mars orbit. The has an effective of 12 meters (f/24) and provides a measuring 1.14 degrees cross-track by 0.18 degrees along-track. Structurally, the instrument measures approximately 1.6 meters in length and 0.9 meters in diameter, with a graphite-fiber-reinforced composite framework for rigidity and low mass. It is mounted on the nadir-pointing deck of the Mars Reconnaissance Orbiter to facilitate downward-looking observations. Thermal control is achieved through an integrated system including radiators to maintain optics at a uniform temperature of about 20°C amid Mars orbital extremes of radiation and temperature fluctuations. The filter system utilizes three broadband filters positioned 30 mm from the detectors: (400–600 nm), (550–850 nm), and near-infrared (800–1000 nm), enabling color imaging without options. The instrument operates at an average power of 60 watts and has a total mass of 65 kg, encompassing the structure, thermal systems, and cabling. HiRISE was constructed by Corp. under oversight from the University of Arizona's Lunar and Planetary Laboratory, with assembly and environmental testing completed to withstand Mars mission conditions including vibration, thermal vacuum, and .

Detector and Imaging Capabilities

The HiRISE instrument employs a focal plane array consisting of 14 charge-coupled device (CCD) detectors, including 10 for broadband red wavelengths (550–850 nm), 2 for blue-green (400–600 nm), and 2 for near-infrared (800–1000 nm), arranged in a staggered 2×7 linear configuration to provide complete cross-track coverage with overlaps of approximately 48 pixels between adjacent detectors. Each CCD features 2048 pixels in the cross-track direction and 128 time-delay integration (TDI) stages in the along-track direction, with a pixel pitch of 12 μm × 12 μm, enabling pushbroom scanning during orbital passes. This arrangement yields a total cross-track swath width of approximately 20,048 pixels for the red channel (corresponding to ~6 km on the surface at nadir) and 4,048 pixels for the color/near-infrared channels, which cover the central portion of the swath. The (GSD) for HiRISE images is determined by the formula
\text{GSD} \approx \frac{\text{pixel size} \times \text{orbit altitude}}{\text{focal length}},
where the size is 12 μm, the effective is 12 m, and typical mapping altitudes range from 255 to 320 km, resulting in a baseline of 25–32 cm/ at for full- (unbinned) imaging. This high supports the production of image pairs, acquired with along-track offsets to enable elevation models (DEMs) with 25 cm horizontal and vertical posting for topographic . The detectors' sensitivity is enhanced by a backside-illuminated with exceeding 65% across 350–900 nm, read noise of 80–120 electrons rms, and full well capacity of approximately 76,000 electrons per under nominal conditions (red channel, 300 km altitude, 128 TDI, no binning), allowing signal-to-noise ratios greater than 100:1 even in low-light scenarios. HiRISE supports flexible imaging modes, including single-image acquisitions for broad coverage, pairs for , and targeted through repeated observations of the same site. These modes utilize selectable TDI levels (8, 32, 64, or 128 stages) to integrate signal along the flight direction and on-chip binning options (1×1 up to 16×16) to balance , , and data volume. A maximum observation in the red band can produce up to 2520 megapixels (e.g., ~20,000 cross-track by 126,000 along-track at 12 bits per ), while color/near-infrared subsets are limited to about 504 megapixels, with total data rates reaching 28 Gb per full image before onboard compression. The optical system's f/24 design, supported by a 0.5 m primary mirror, focuses onto the detectors to achieve the 1 μrad instantaneous per essential for this performance.

Operations

Acquisition and Data Handling

Observation planning for HiRISE images is conducted in two-week cycles by the science team at the of Arizona's HiROC operations center, where co-investigators submit prioritized requests based on 18 scientific themes such as recurring slope lineae, layered deposits, and landing site certification. These requests are integrated into the (MRO) master schedule by NASA's (JPL), which uses an automated planner to allocate observation slots while balancing demands from other instruments and mission constraints like thermal limits and orbital geometry. Target selection emphasizes high-priority science goals and mission support functions, including public suggestions via the HiWish program, with off-nadir pointing enabled by MRO's agile slew capabilities to image sites up to 30 km from , allowing for stereo pairs and repeat observations of dynamic features. The image capture sequence employs a pushbroom with 14 () detectors arranged in a focal plane, each capturing a swath of the surface as MRO orbits at approximately 255 km altitude. Exposure occurs via time-delay integration (TDI), where light from a ground line is integrated across 8 to 128 rows at line rates of 80–100 µs, resulting in effective integration times of about 0.01 s for maximum TDI to minimize along-track smearing from motion; higher stability modes are prioritized to keep smear below . binning (1×1 to 16×16) and selective activation adjust resolution and coverage, with typical full-resolution images spanning 5–6 km cross-track and up to 40 km along-track at 25–32 cm/, while color imaging covers the central 1.2 km using red, blue-green, and near-infrared bands. Raw HiRISE data from a full-resolution can reach up to 28 gigabits uncompressed at 14 bits per , but onboard applies look-up (LUT) conversion to 8 bits per (reducing volume by ~1.75:1) followed by lossless FELICS with an average ratio of ~2.5:1, yielding transmitted volumes typically up to 11.2 gigabits per . This preserves all information while fitting within MRO's solid-state capacity of 28 gigabits dedicated to HiRISE. at HiROC further applies lossless JPEG2000 for reduced records (RDRs), enabling efficient and . Transmitted data are downlinked from MRO via its X-band radio at frequencies around 8.4 GHz to NASA's Deep Space Network antennas, with peak rates up to 6 megabits per second during optimal geometry, though effective rates average 0.5–4 Mbps depending on distance and scheduling. HiRISE typically acquires and transmits about 60–100 images per week during nominal operations, constrained by the 48% downlink allocation shared with other instruments post-CRISM retirement in 2022. Data receipt at JPL is followed by rapid transfer to HiROC for and product generation, with browse products released weekly. As of , HiRISE has acquired over 99,000 images, covering about 5% of Mars' surface at sub-meter resolution, with operations continuing daily to support ongoing and future mission planning amid challenges like failures and dust storm-induced data losses. The instrument's endurance has enabled persistent monitoring, with recent acquisitions including targeted imaging of objects and sites, sustaining MRO's role beyond its primary phase that began in 2006.

Calibration and Adaptations

Initial calibration of the HiRISE instrument encompassed comprehensive pre-launch ground tests conducted at Ball Aerospace, where over 7,000 images were acquired to evaluate functional performance, reliability, optical quality, and radiometric response. These tests utilized a 30-inch to produce focused images of bar targets and pinholes, confirming a of approximately 20% at the and a with a of about 1.5 pixels. In-flight calibration commenced shortly after the Mars Reconnaissance Orbiter's arrival at Mars, with the first dedicated observations targeting the on September 8, 2005. Three scans were performed at a of 0.05° per second, employing 32 or 64 time delay integration lines, full resolution for inner (CCD) channels, and 4×4 pixel binning for outer channels to assess focus, distortions, and (SNR). Subsequent in-flight calibration in December 2005 imaged the Jewel Box open (NGC 4755) in the constellation to refine flat-fielding, focus adjustments, and characterization, while also testing interactions with the Compact Reconnaissance Imaging Spectrometer for Mars . Early operational challenges included radiation-induced degradation, with cosmic ray damage contributing to bit-flips and hot pixels across channels, notably affecting image quality in the initial years following the deployment. By , two spacecraft safing events occurred due to solid-state recorder overloads, temporarily halting observations on September 27 and November 7, which highlighted vulnerabilities in handling under . failures progressed over time, with the RED9 channel ceasing in —reducing the red swath width by 10%—and the RED4 channel failing in 2023, creating a central gap in coverage; these issues stemmed from cumulative proton and cosmic ray damage in the Martian orbital environment. To mitigate bit-flip degradation, particularly in RED5 and RED6 channels, periodic thermal annealing via controlled heating was implemented, elevating focal plane temperatures to restore charge trap recovery and achieve over 95% performance restoration in affected detectors. Ongoing adaptations have addressed evolving operational constraints through software enhancements and procedural adjustments. The HiPlan planning suite received iterative updates to improve pointing accuracy, incorporating Fourier-based jitter correction algorithms that resolve spacecraft vibrations to sub-pixel levels and update instrument pointing kernels for sharper imagery. Post-2018, power margins tightened due to solar array degradation and thermal management demands, prompting reduced maximum image lengths—from 120,000 lines in bin-1 mode during the primary phase to 55,000 lines by —to conserve energy for focal plane electronics heating, which eliminated optical blur but limited data volume per observation. By , integration of algorithms enhanced target prioritization, automating detection of transient features like new impact craters and slope streaks from prior HiRISE and Context Camera datasets to guide high-resolution follow-ups. Performance monitoring involves annual assessments of key metrics, including SNR in the red band (550–850 nm), which has consistently exceeded the design goal of >100:1 at full resolution through optimized time delay integration and backside-thinned CCDs, despite minor read noise shortfalls in some channels. Lifetime radiation exposure for the instrument reached approximately 10^{11} protons/cm² by 2025, primarily from galactic cosmic rays and solar energetic particles, necessitating vigilant tracking of CCD charge transfer inefficiency via the Hi5 health monitoring tool for voltages, temperatures, and bit-error rates. Future-proofing efforts focus on sustaining operations through the Mars Reconnaissance Orbiter's anticipated mission end between 2027 and 2030, with data rates dynamically adjusted for aging components such as increasing bit-flip rates and reduced availability; this includes shifting toward more 2×2 binned acquisitions over full-resolution modes to maintain coverage efficiency while preserving scientific return.

Scientific Contributions

Key Discoveries

HiRISE imagery has revealed compelling evidence of ancient fluvial activity on Mars through the identification of well-preserved alluvial fans and deltas, particularly in Holden Crater, where layered sedimentary deposits indicate prolonged water flow and sediment deposition dating back over 3.5 billion years. These features, imaged in 2007, suggest episodic lake formation and overflow events in breached craters, reshaping our understanding of early Martian . Similarly, deltaic structures in nearby Eberswalde Crater exhibit stratigraphic layering consistent with sustained liquid water environments, supporting models of a wetter ancient Mars. Recurring slope lineae (RSL), first extensively documented by HiRISE starting in 2011, appear as dark, linear streaks on steep slopes that lengthen during warmer seasons, likely formed by transient briny flows involving hydrated salts. Observations through multiple Mars years show RSL activity concentrated in equatorial regions, with spectral data indicating the presence of perchlorates that lower the freezing point of , enabling brief flows despite current aridity. These findings imply ongoing geochemical processes that could harbor microbial life, though dry granular flow remains a competing hypothesis. A 2025 study using HiRISE data supports the dry granular flow hypothesis over briny flows. In impact crater analysis, HiRISE has captured fresh craters that expose subsurface volatiles, such as the 150-meter-wide crater in Amazonis Planitia formed on December 24, 2021, which ejected large blocks of nearly pure water ice from depths of up to 20 meters. This event, confirmed by seismic detection from NASA's InSight lander, highlights the widespread distribution of shallow ice reserves in mid-latitudes. HiRISE monitoring has identified approximately 200 new small craters (diameters 4-20 meters) annually across the planet, providing a refined estimate of the current impact flux and enabling precise dating of recent surface modifications. These detections have revised Mars crater chronology models by incorporating higher recent production rates, resulting in model ages for surfaces 3–5 times younger than previously estimated. HiRISE has documented dynamic surface changes, including seasonal avalanches at the in 2008, where CO2 frost and dust cascades down scarps at speeds exceeding 100 km/h, driven by during spring. Monitoring of activity reveals fresh deposits in tens of sites, with alcove-channel-fan systems showing recent erosion and deposition linked to CO2 destabilization or melting. Dune migration is evident planet-wide, with ripples advancing 1-10 meters per Martian year under current winds, as seen in Nili Patera and polar ergs. Recent techniques in 2024, combining HiRISE with multi-temporal analysis, have mapped exposures in craters like S1094b, quantifying deposit degradation rates and confirming unstable, pure water layers. Atmospheric and ice-related discoveries include the detection of CO2 jets that erupt from seasonal polar caps, ejecting dark material and forming spider-like troughs through explosive sublimation in spring. HiRISE has tracked seasonal frost patterns, revealing CO2-dominated caps in winter that retreat unevenly, with water emerging in residual deposits. Global mapping efforts, supported by HiRISE imaging of exposures, have delineated near-surface water ice equivalents, with estimates indicating volumes exceeding 10^6 km³ in mid-to-high latitudes, crucial for resource assessments. Quantitatively, HiRISE contributions have overhauled crater chronology by validating elevated impact rates, which recalibrated age models for Amazonian surfaces and supported 2025 studies on polar ice stability, indicating oscillatory climate cycles with potential recent ice loss amid . These updates align with broader climate models, emphasizing the role of volatiles in Martian .

Notable Image Examples

One of the earliest notable HiRISE images captured Victoria Crater at Meridiani Planum on October 6, 2006 (TRA_000873_1780), revealing intricate layered sediments along the crater's walls that provided crucial geological context for NASA's Opportunity rover exploring the nearby region. The image highlighted the crater's scalloped rim and interior dunes, showcasing the instrument's ability to resolve fine-scale features at approximately 800 meters in diameter. HiRISE has frequently imaged landing sites to support surface missions, including the Phoenix lander's descent stage on May 25, 2008 (PSP_008579_9020), which depicted the parachute, backshell, and heat shield scattered across the northern plains shortly after touchdown. Similarly, a recent HiRISE Picture of the Day from February 28, 2025 (ESP_085807_1590), captured NASA's Curiosity rover mid-drive in Gale Crater, appearing as a dark speck amid its wheel tracks spanning over 300 meters, illustrating ongoing monitoring of rover mobility and terrain interactions. Dynamic surface processes are vividly demonstrated in HiRISE images of seasonal phenomena, such as the north polar avalanches observed in early 2008 (PSP_007338_2640), where multiple debris flows of frost and dust cascaded down steep scarps in Chasma Boreale, captured mid-motion for the first time on Mars. Another example is a fresh impact site in the region documented in 2010, featuring a small with prominent bright rays contrasting against the dark plains, indicating recent bombardment and subsurface material exposure. Public engagement through the HiWish program has led to targeted imaging, including a 2012 observation of Mawrth Vallis (ESP_028855_2045) that exposed diverse clay-bearing layers in an eroded crater, highlighting the region's phyllosilicate diversity and potential habitability indicators as requested by citizen scientists. Stereo imaging capabilities shine in paired observations like those of Endeavour Crater in 2011 (ESP_024015_1775 and companion), which enabled the creation of 3D elevation models with approximately 1-meter vertical accuracy, aiding analysis of the crater's rim structures investigated by the Opportunity rover.

Data Management

Naming Conventions

The HiRISE images are identified using a standardized observation ID format consisting of three main components: a three-character mission phase code, a six-digit number, and a four-digit code, typically expressed as "ppp_oooooo_llll" where "ppp" denotes the mission phase (e.g., TRA for the initial trajectory phase in 2006, for the primary phase from 2006 to 2010, and for extended phases post-2010), "oooooo" is the zero-padded number, and "llll" is the code representing the approximate sub-spacecraft in tenths of a from the descending equatorial node (e.g., 0090 for a location near 0.90°N, or 1780 approximating 17.80°S near 180°E , though is not directly encoded). Additional codes extend this base ID for specific data products, including a filter identifier "f" (R for , B for , or I for near-infrared) and a color mode "c" (e.g., _RED for single-band images or _COLOR for three-band combinations of , , and near-infrared). For raw experimental data records (EDRs), the full filename incorporates the , such as "PSP_001687_0090_RED5_0.IMG", while reduced data records (RDRs) use processed formats like "PSP_001687_0090_RED.JP2" for JPEG2000 compressed images or ".IMG" for mosaicked observations. This naming convention evolved from the initial TRA phase during spacecraft approach and in 2006 to accommodate extended mission operations after 2010, with ESP replacing PSP to reflect ongoing phases while maintaining in the Planetary (PDS) archives. The structure facilitates rapid geolocation, phase identification, and chronological sorting of nearly 100,000 images in PDS repositories as of November 2025, enabling efficient catalog navigation and data retrieval for researchers.

Archival and Public Access

The primary archive for HiRISE data is hosted by NASA's Planetary Data System (PDS) Imaging Node, which curates and distributes the mission's products to ensure long-term for scientific and use. All standard data products, including raw and processed images, are released to the PDS on a monthly cadence, typically within two months of acquisition to balance processing needs with timely availability. HiRISE undergoes a multi-stage processing at the HiRISE Operations Center (HiROC) at the , transforming raw Experiment Data Records (.IMG format) into map-projected Reduced Data Records in JPEG2000 (.JP2) format for efficient compression and viewing. Following the July 2023 hardware anomaly that disabled one , processing were updated to incorporate near-infrared () to maintain color capabilities across the swath. Additional derived products, such as color composites from , , and near-infrared channels, as well as anaglyphs for visualization, are generated during this to support geological and public engagement. Public access to HiRISE data is facilitated through the official HiRISE website (hirise.lpl.arizona.edu), which features a searchable catalog of observations, the HiView image viewer for exploring full-resolution JPEG2000 files, and the HiRISE Picture of the Day (HiPOD) feature that has highlighted daily or featured images since the mission's primary science phase began in 2006. The Java Mission-planning and Analysis for Remote Sensing (JMARS) tool, an open-source geospatial application, allows users to visualize HiRISE data layers alongside other Mars datasets for planning and analysis. All data is openly accessible under NASA's public data policy, enabling unrestricted download and use by researchers and the general public. As of November 2025, the HiRISE archive includes nearly 100,000 observations, encompassing more than 100 terabytes of data products ranging from raw telemetry to enhanced mosaics and digital terrain models. Recent enhancements include the 2023 application of deep learning techniques, such as convolutional neural networks, to automate feature detection and generate high-resolution digital terrain models from HiRISE stereo pairs, improving efficiency in mapping complex Martian surfaces like Jezero Crater.