How to Capture a High-Resolution View of Mars' South Pole During a Spacecraft Flyby

Introduction

On May 15, 2026, NASA's Psyche mission achieved a remarkable feat: during a gravity assist flyby of Mars, it captured the highest-resolution image ever taken of the planet's water ice-rich south polar cap. The image, acquired with the spacecraft's Imager A, shows details at a scale of about 0.7 miles per pixel (1.14 km/pixel) across a cap extending more than 430 miles (700 km). This guide explains the step-by-step process behind such a planetary imaging achievement—from trajectory planning to final data analysis. Whether you're a mission planner, a space enthusiast, or a student, these steps outline the critical decisions and actions needed to obtain a stunning scientific image during a spacecraft flyby.

What You Need

• Spacecraft with a high-resolution camera – e.g., Psyche's Imager A, capable of capturing visible-light images with sufficient resolution for surface features.
• Accurate orbital trajectory – A flyby path that brings the spacecraft close enough to the target (in this case, Mars' south pole) for high-resolution imaging.
• Knowledge of the target's rotation and illumination – To time the image capture when the pole is in sunlight and oriented favorably.
• Precise timing and attitude control – The ability to point the camera exactly at the desired region at the exact moment of closest approach.
• Data processing software – Tools to convert raw image data into the final high-resolution view, including calibration and mosaicking.
• Gravity assist plan – A trajectory that uses the planet's gravity to alter speed and direction, while also allowing scientific observations.

Step-by-Step Guide

Step 1: Plan the Gravity Assist Trajectory

Begin by designing a spacecraft trajectory that not only provides the necessary gravitational slingshot but also passes close to the target region. The Psyche mission's trajectory was carefully computed to use Mars' gravity to accelerate the spacecraft toward the main asteroid belt, while simultaneously passing within optimal distance of the south polar cap. Use orbital mechanics simulations to ensure the flyby altitude is low enough to achieve your desired image resolution—here, the final image scale of 0.7 miles per pixel was achieved. Coordinate with navigation and science teams to prioritize the polar cap as a key observation target during the flyby.

Step 2: Calibrate the Imager

Before the flyby, thoroughly calibrate the onboard camera. For Psyche's Imager A, this involved flat-field corrections, dark current subtraction, and radiometric calibration to ensure accurate radiance measurements. Test the camera's sensitivity and focus on known star fields or celestial targets. Adjust exposure settings based on predicted lighting conditions at Mars' south pole—the region is illuminated by low-angle sunlight, so you may need longer exposures or higher gain. Also, set up the camera's data compression and storage to handle the high-resolution images expected during the flyby window.

Step 3: Determine Optimal Observation Timing

Use ephemeris data to calculate the exact moment when the spacecraft is closest to the south polar cap, and when the lighting is optimal. The image was captured at 1:53 p.m. PDT on May 15, 2026, during the spacecraft's closest approach. Consider Mars' rotation: the south pole is visible for only a portion of the flyby. Allow for buffer time to account for trajectory uncertainties. Also, plan for multiple images in a sequence to increase the chance of capturing the best view and to create a mosaic if needed.

Step 4: Acquire the Image During Closest Approach

Execute the image acquisition sequence precisely at the pre-calculated time. Command the spacecraft to point Imager A toward the south polar cap, stabilize attitude, and trigger the exposure. The Psyche mission's system was designed to autonomously perform this sequence. For best results, take a rapid series of images—some with different filters if available—to capture spectral information. Monitor telemetry to confirm the images are stored successfully. After the flyby, download the raw data to Earth for processing.

Step 5: Process and Interpret the Data

Once the raw image data arrives at mission control, process it using calibration files to remove sensor artifacts. Apply geometric corrections to account for the spacecraft's motion and the planet's curvature. The final image of the south polar cap had a scale of 0.7 miles per pixel; you may need to combine multiple frames to improve signal-to-noise ratio. Interpret the image to study the water ice-rich cap, its extent (over 430 miles), and surface features. The data also supports broader science goals, such as understanding the cap's seasonal changes and composition. Publish the findings and release the image to the public, as NASA did with this Psyche image.

Tips for Success

• Coordinate with multiple mission phases: Ensure the imaging sequence doesn’t interfere with the gravity assist navigation requirements. Early integration of science and engineering teams is critical.
• Account for lighting constraints: Polar regions receive sunlight at shallow angles, creating long shadows that enhance topography but require careful exposure management. Consider imaging during the summer solstice for maximum illumination.
• Use the flyby for more than just gravity: Even a brief encounter can yield invaluable science. Plan for a “Science Opportunity” window weeks in advance.
• Back up your data: Store images in multiple formats and transmit them multiple times to avoid data loss. The Psyche mission had robust redundancy.
• Engage the public early: A high-resolution image like this one generates excitement. Prepare a press release and outreach materials to share the results quickly after processing.
• Learn from past missions: Study how other flybys (e.g., Galileo, New Horizons) optimized their imaging. The Psyche team built on decades of experience.

Following these steps, you can successfully capture a high-resolution view of a planetary pole during a spacecraft flyby, contributing to our understanding of the solar system. The Psyche mission's image stands as a testament to careful planning, precise execution, and the joy of discovery.