SBIR-STTR Award

Ultra scaling of SPAD arrays for high-speed laser ranging
Award last edited on: 11/16/2018

Sponsored Program
STTR
Awarding Agency
DOD : Navy
Total Award Amount
$1,149,998
Award Phase
2
Solicitation Topic Code
N15A-T011
Principal Investigator
Eric S Harmon

Company Information

Lightspin Technologies Inc

616 Lowell Drive
Endwell, NY 13760
   (301) 656-7600
   info@lightspintech.com
   www.lightspintech.com

Research Institution

University of Virginia

Phase I

Contract Number: N00253-15-P-0316
Start Date: 7/23/2015    Completed: 3/7/2017
Phase I year
2015
Phase I Amount
$150,000
Ultrasensitive detection of visible light has a wide range of applications, including laser ranging and free-space optical communications. Ultimate sensitivity is achieved when individual return photons are counted with high probabilities of detection, low probabilities of false counts, and high bandwidth. Previously, Vacuum photomultiplier tubes provided good single photon detection sensitivities but with limited bandwidth, while semiconductor solutions provide high bandwidth or high sensitivity, but not both. LightSpin proposes to develop a novel semiconductor solution to bridge the gap between bandwidth and ultimate sensitivity. The approach recognizes ultra-scaling of single photon avalanche diode (SPAD) arrays enables substantial improvements in bandwidth to be achieved. The approach uses GaInP, a wide band gap compound semiconductor with superior characteristics for high speed detection of visible light with low noise. The Phase I goal is to achieve single photon sensitivities at bandwidths approaching 1 GHz, laying the foundation for a Phase II effort to extend the bandwidth to 10 GHz.

Benefit:
The proposed ultra-scaling of SPAD arrays has the potential to achieve bandwidths approaching 10 GHZ and gain-bandwidth products approaching 100 THz, outperforming all competing, room temperature approaches. Target commercial applications include lidar (projected market value of $0.5B in 2018) and free space optical communications ($50M in 2018). LightSpins initial approach is targeted for highest performance for visible light, but is readily extended to the near infrared wavelengths commonly used for automobile lidar and autonomous robotic applications. Achieving an order of magnitude higher sensitivity will enable these lidar systems to achieve increased range and lower cost, providing a substantial advantage to the consumer.

Keywords:
single photon, single photon, free-space optical communications, APD, single photon avalanche diode, SPAD, LIDAR, SiPM, Avalanche photodiode

Phase II

Contract Number: N00253-17-C-0003
Start Date: 5/19/2017    Completed: 5/18/2019
Phase II year
2017
Phase II Amount
$999,998
Ultrasensitive detection of visible light has a wide range of applications, including laser ranging and free space optical communications. Ultimate sensitivity is achieved when individual return photons are counted with high probabilities of detection, low probabilities of false detection, and precision timing. Previously, high bandwidth was only achieved with PIN photodiode and avalanche photodiodes, with detection limits of 1000 and 100 photons respectively, though bandwidth in excess of 10 GHz is feasible. LightSpin Technologies, Inc. proposed that scaling of single photon avalanche diode (SPAD) arrays to very tight pitches could be expected to achieve bandwidths in excess of 1 GHz, for the first time enabling simultaneous single photon detection and wide bandwidth operation in a solid-state detector. In Phase I, LightSpin demonstrated the capability to scale SPAD arrays to 11 micron pitch and demonstrated a bandwidth improvement in agreement with theory. In Phase II, we propose to continue the scaling effort to 5 micron pitch, enabling GHz and multi-GHz detection bandwidth with single photon sensitivity.

Benefit:
The proposed ultra-scaling of SPAD arrays has the potential to achieve bandwidth approaching 10 GHz and gain-bandwidth products approaching 100 THz, outperforming all room-temperature alternatives. Single photon counting modules and avalanche photodiodes markets are $246M/year and $167M/year respectively as a part of the total global photonic detectors market growing at a compounded annual growth rate (CAGR) of 15% through 2019. Avalanche photodiodes are a critical component of many high performance lidar systems, and achieving an order of magnitude improvement in detection sensitivity translates directly to increased range, reduced transmitted laser power, and lower cost. LightSpins approach is a platform technology that can be readily adapted to not only address visible light photodetection, but also near infrared and eye-safe wavelengths critical to many commercial lidar systems.

Keywords:
Geiger Mode, APD, single photon avalanche diode, Avalanche photodiode, SPAD, SPAD array, SiPM