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LIDAR using on-chip optical phased arrays

Written by Sachin | May 16, 2022 7:48:37 PM

LIDAR BASICS

  • LIDAR is based on well known principles of RADAR
  • Radar is well known technology existing since the beginning of the 20th century
  • LIDAR uses optical frequencies instead of radio waves

Lidar and Radar

 

LIDAR using phased arrays improves directionality using interference

  • Output profile of a LIDAR is the product of the array factor and the single antenna far field.

 

N: number of antennas

k: wave vector

w_i: complex weight for element I

r_i: position vector for antenna element i

LIDAR using on-chip waveguide antennas

  • Corrugated waveguides are used as antennas
  • Pitch corrugation is chosen so that Bragg reflected light is scattered to free space
  • Multiple such antennas are used in an array to for beam forming

Lidar modeling in Lumerical

  • MODE analysis of waveguide to calculate n_eff
  • Choosing optimum antenna separation so that there is minimum coupling between adjacent antennas
  • 3d FDTD simulation to calculate bandgap region
  • Far field analysis to calculate far-field profile of a single antenna
  • Array factor multiplication to see beam steering

Mode

Calculate effective refractive index for thinner and thicker cross-sections

  • Optimizing separation to minimize cross-coupling
  • We perform simulations with 2 waveguides and calculate after how much length can 10% of light from waveguide 1 couple to waveguide 2

FDTD

  • Calculate the band-gap region
  • Observe wavelength dependent single antenna scattering



  • 2d beam-steering(θ,ϕ) using results from FDTD

System level simulations using INTERCONNECT

  • Integrate multiple components
  • Simulate an actual experiment
  • Extensive library of standard components
  • Custom components can be created
  • Allows integration of optical, electrical and thermal elements


  • We see the effect of applying a optical delay using a voltage ramp on an optical modulator
  • For a given range of voltage values we can monitor θ,ϕ of the steered beam and beam properties.

Beam Steering

 

Detector design

  • Detector design using Lumerical
  • Optical simulations to study light absorption in detectors

Example: We look at Germanium detectors on Si

Ge on Si detector cross-section

Intensity profile in Ge using FDTD

  • Electrical simulations using CHARGE can be used to calculate the photocurrent and the dark current for the detector
  • Electrical simulations using CHARGE can be used to calculate the responsivity and gain

  • Circuit simulations using INTERCONNECT can be used to simulate detector response to weak modulated signal