Abstract: A Ground Penetrating Radar (GPR) system makes use of digital circuitry for synchronizing the sampling of a received radar signal with a transmitted radar signal. The digital synchronization achieves improved waveform reproduction and greater receiver sensitivity. Furthermore, the system employs digital circuitry to control the gain of a receiver amplifier. The digitally controlled gain makes it possible to accurately calibrate the amplitude of received radar signals with great precision while achieving good dynamic range.

Abstract: Ground-penetrating radar (GPR) technology enables the detection of hidden objects that are underground or behind walls or other such surfaces. Embodiments of the present invention provide a realistic visualization of the hidden objects through so-called augmented reality techniques. Thanks to such visualization, interaction with hidden objects that are hazardous or delicate is easier and less prone to errors. Also, GPR-based data collection can be performed in non-real time, with object visualization occurring at a later time based on stored data that can also comprise annotations. This capability provides greater flexibility for scheduling activities related to the hidden objects.

Abstract: A Ground Penetrating Radar (GPR) system makes use of digital circuitry for synchronizing the sampling of a received radar signal with a transmitted radar signal. The digital synchronization achieves improved waveform reproduction and greater receiver sensitivity. Furthermore, the system employs digital circuitry to control the gain of a receiver amplifier. The digitally controlled gain makes it possible to accurately calibrate the amplitude of received radar signals with great precision while achieving good dynamic range.