Mission Timeline: Mars Orbit Insertion - Doppler Plot

Learn about what happened step by step!

Doppler Plot with Status Updates Doppler Animation Small version: QuickTime | MPEG Large version: QuickTime | MPEG

When Mars Reconnaissance Orbiter went through its critical engine firing during orbit insertion, the mission team closely followed a graph called the Doppler plot. The picture-perfect pattern meant Mars Reconnaissance Orbiter had been captured as planned in orbit around Mars!

Here's what the pattern showed:

• The plot dropped at the point when the main engine burned, showing an expected decline in velocity during orbit insertion.
   
• The gap in the line showed the predicted time when the spacecraft lost lock with ground stations on Earth as it passed behind Mars (as viewed from Earth), and the planet blocked its signal.
   
• Engineers waited expectantly for the signal to reappear as the orbiter emerged from behind Mars and was able to communicate with Earth once again.
   
• The small white line showed when the spacecraft emerged from behind the planet and one-way communications were established.
   
• The green line showed when two-way communications were reestablished, with the slope of the line leveling as the orbiter's velocity became slower and steadier.
   

Most people are familiar with the phenomenon of a car horn or train whistle changing its frequency as it moves toward or away from them. Electromagnetic radiation (light waves or radio signals) also experiences this effect. The size of the frequency shift, or "Doppler shift," depends on how fast the light source is moving relative to the observer. Astronomers often refer to the "redshift" and "blueshift" of visible light, where the light from an object coming toward us shifts to the blue end of the spectrum (higher frequencies) and light from an object moving away from us shifts toward the red (lower frequencies).

Mars Reconnaissance Orbiter communicated with controllers on the ground by radio signal. Ground controllers knew the frequency of the signal emitted from the spacecraft. As the spacecraft was moving away from (or toward) the Earth, the radio frequency experienced a Doppler shift to a different frequency. Engineers (or, more accurately, computers) compared the received frequency with the emitted frequency to measure the Doppler shift. It was then a straightforward calculation to determine the velocity that caused the observed Doppler shift.