How radar works

On this page we’ll explain radar sensing and show you the anatomy of a radar – the typical components contained on a printed circuit board.

 

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How radar works

We’ll start with a simple explainer of radar sensing feel free to skip this part if you are already a radar expert, and head straight to space sensing – why radar wins.

Imagine you are standing in a pitch-black room, firing rubber balls in every direction. Some will hit surfaces that bounce them straight back at you. If you know the speed and direction of the ball, and you time how long it takes to hit you (and you are good at mental arithmetic), you could work out the positions of the rebounding surfaces. Taking all those data points, you could build up a picture of the room around you.

Radar sends out electromagnetic (EM) waves rather than rubber balls, but the principle is analogous – we measure the reflections and use it to calculate the position of objects relative to the radar.

We can be more accurate than our ball firer, measuring precise positions of objects, and even features on objects, in some cases down to millimeter accuracy. We can even measure how the object is moving by looking at frequency changes in the returned wave, known as Doppler shift.

All of which of course needs a very precise signal, very precise measurement, and carefully designed algorithms that turn information embedded within the electromagnetic waves into actionable data on what is being seen, for by humans or machine decisions.

The anatomy of a radar

  • 01
    Frequency synthesizer

    Generates the signal.

  • 02
    Amplifier

    Amplifies the signal.

  • 03
    Modulator

    Controls the frequency as the signal moves across its bandwidth.

  • 04
    Antenna

    Transmits the signal into space.

  • 05
    Receiving antenna

    Receives the signal response (there may be many of these in an array).

  • 06
    Low noise amplifier

    Amplifies the return signal. This needs to be very efficient to amplify signal and remove any noise.

  • 07
    Demodulator

    Extracts data from the signal by removing modulation (the signal contains information waves and carrier waves. Demodulation removes the carrier waves, like taking a letter out of an envelope).

  • 08
    Analog to digital converter

    Digitize to extract information into a digital format.

  • 09
    Post Processing

    Classification to use relevant information to define what has been detected.

The anatomy of a radar
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Radar technology delivers superior range, all-weather performance, and cost-effective design for space missions compared to optical alternatives.

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Plextek's white paper Sensing in Space
Plextek's white paper Sensing in Space Plextek's white paper Sensing in Space

Technical Paper – Sensing in Space

Explore the cutting-edge technology of mmWave radar and its impact on space missions in our technical paper “Sensing in Space”. Gain insights into safety and efficiency improvements, customization options, and performance optimization. Stay informed about the latest advancements in space technology.
Download "Sensing in Space" now
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