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In new designs, the Aura sensors enable 12X greater LiDAR image resolution for a given laser power, up to 30% reduction in system size and weight, and up to 40% lower system costs. The size and cost reductions come from using lower-power lasers and smaller optical apertures without impacting system performance. Also, thermal management is simplified because Aura APDs operate at up to +85 °C without performance degradation, which is a significantly higher temperature than traditional parts.
Phlux created its Noiseless InGaAs APD technology by adding an antimony alloy to the compound semiconductor manufacturing process. The resulting sensors can be operated with APD gains up to 120, enabling even the smallest signals above the noise floor of a connected trans-impedance amplifier (TIA) to be amplified. A further benefit of Aura APDs is their rapid overload recovery, which means that weaker secondary pulses that closely follow a large pulse can be detected.
The Aura APD 200 (200 µm optical aperture) and Aura APD 80 (80 µm optical aperture) sensors are available as bare die or in industry-standard SMD, chip on sub-mount, and TO-46 packages designed to meet MIL-STD 883.
Typical parameters for both devices are responsivity of 0.98 A/W at 1550 nm, spectral range of 950 nm to 1700 nm, and excess noise factor of 1.86 at an avalanche gain of 40, or 1.08 at an avalanche gain of 10.
At a gain of 10, the noise equivalent power for the Aura APD 200 diode is 17 fW/Hz0.5, its capacitance 2.4 pF, and its cut-off frequency 0.7 GHz. The equivalent figures for the Aura APD 80 are 11.1 fW/Hz0.5, 0.6 pF, and 1.8 GHz.
Both devices have a typical operating voltage of -55 to -65 V and a breakdown voltage of -65 V, and their operating temperature range is -40 °C to +85 °C.
These sensors are in production now.
Filed Under: Sensor Tips