Hyper Temporal Lidar with Dynamic Laser Control and Shot Order Simulation

1 . A lidar apparatus comprising: a laser source; a mirror that is scannable to define where the lidar apparatus is aimed along an axis within a field of view, wherein the mirror is optically downstream from the laser source; and a control circuit that (1) controls a variable rate firing of laser pulse shots by the laser source that are targeted, via the mirror, toward a plurality of range points in the field of view that are members of a pool of range points, (2) for the pool of the range points, performs a plurality of simulations of different shot order candidates for laser pulse shots which target the range points in the pool with respect to a laser energy model that models how much energy is available from the laser source for laser pulse shots over time as compared to a plurality of energy requirements for the targeted laser pulse shots, wherein the simulations include removal of one or more range points from the pool if none of the shot order candidates exhibit simulated available energies for the targeted laser pulse shots that satisfy the energy requirements until a shot order candidate is found for the pool that exhibits simulated available energies for the targeted laser pulse shots that satisfy the energy requirements, and (3) determines a shot order of the targeted laser pulse shots for the variable rate firing based on the simulations. 2 . The apparatus of claim 1 wherein the control circuit comprises parallelized logic resources that perform the simulations in parallel. 3 . The apparatus of claim 2 wherein the control circuit comprises an application-specific integrated circuit (ASIC), and wherein the parallelized logic resources comprise parallelized hardware logic on the ASIC. 4 . The apparatus of claim 2 wherein the control circuit comprises a field programmable gate array (FPGA), and wherein the parallelized logic resources comprise parallelized hardware logic on the FPGA. 5 . The apparatus of claim 2 wherein the control circuit comprises a system on a chip (SoC), and wherein the parallelized logic resources are resident on the SoC. 6 . The apparatus of claim 1 wherein the control circuit performs the simulations by simulating the available energies for the targeted laser pulse shots with respect to the different shot order candidates according the laser energy model; and wherein the control circuit determines the shot order by selecting one of the shot order candidates to use as the determined shot order based on which of the shot order candidates exhibit simulated available energies for the targeted laser pulse shots that satisfy the energy requirements. 7 . The apparatus of claim 6 wherein the selected shot order candidate comprises the shot order candidate with a shortest completion time if a plurality of the shot order candidates exhibit simulated available energies for the targeted laser pulse shots that satisfy the energy requirements. 8 . The apparatus of claim 1 wherein the control circuit controls the variable rate firing by generating firing commands for the laser source in accordance with the determined shot order. 9 . The apparatus of claim 1 wherein the mirror is scannable through a plurality of scan angles to define where the lidar apparatus is aimed along the axis in the field of view; wherein the range points to be targeted with the laser pulse exhibit corresponding scan angles along the axis; and wherein the control circuit generates the different shot order candidates according to a mirror motion model that models the scan angles for the mirror over time. 10 . The apparatus of claim 9 wherein the mirror motion model models the scan angles for the mirror as a plurality of corresponding time slots, and wherein the control circuit generates the shot order candidates by assigning the laser pulse shots targeting the range points to time slots corresponding to the scan angles exhibited by the range points to be targeted by the laser pulse shots. 11 . The apparatus of claim 10 wherein the control circuit simulates the available energies for the shot order candidates based on lookups from a lookup table (LUT) of pre-computed values of available energies for laser pulse shots from the laser source at different time slots of the mirror motion model. 12 . The apparatus of claim 10 wherein the time slots reflect time intervals in a range between 5 nanoseconds and 50 nanoseconds. 13 . The apparatus of claim 9 wherein the mirror motion model models the scan angles according to a cosine oscillation. 14 . The apparatus of claim 1 wherein the control circuit drives the mirror to scan along the axis in a resonant mode. 15 . The apparatus of claim 14 wherein the mirror comprises a first mirror, wherein the axis comprises a first axis, the apparatus further comprising a second mirror that is scannable along a second axis within the field of view, and wherein the control circuit drives the second mirror to scan in a point-to-point mode based on the range points in the field of view to be targeted with the fired laser pulse shots. 16 . The apparatus of claim 1 wherein the control circuit drives the mirror to scan along the axis at a frequency between 100 Hz and 20 kHz. 17 . The apparatus of claim 1 wherein the control circuit drives the mirror to scan along the axis at a frequency between 10 kHz and 15 kHz. 18 . The apparatus of claim 1 wherein the laser energy model (1) models a depletion of energy in the laser source in response to each laser pulse shot, (2) models a retention of energy in the laser source after laser pulse shots, and (3) models a buildup of energy in the laser source between laser pulse shots. 19 . The apparatus of claim 1 wherein the laser source comprises an optical amplification laser source. 20 . The apparatus of claim 19 wherein the optical amplification laser source comprises a pulsed fiber laser source. 21 . The apparatus of claim 20 wherein the pulsed fiber laser source comprises a seed laser, a pump laser, and a fiber amplifier, and wherein laser energy model models (1) seed energy for the pulsed fiber laser source over time and (2) energy stored in the fiber amplifier over time. 22 . The apparatus of claim 21 wherein the laser energy model models the available energy for laser pulse shots according to a relationship of EF(t+δ)=aS(t+δ)+bEF(t), wherein a+b =1 so that a and b reflect how much energy is drained from and remains in the fiber amplifier when laser pulse shots are fired, wherein EF(t) represents laser energy for a laser pulse shot fired at time t, wherein EF(t+δ) represents laser energy for a laser pulse shot fired at time t+δ, wherein S(t+δ) represents an amount of energy deposited by the pump laser into the fiber amplifier over time duration δ, wherein t represents a fire time for a laser pulse shot, and wherein the time duration δ represents intershot spacing in time. 23 . The apparatus of claim 19 wherein the laser energy model (1) models depletion of energy in an optical amplifier of the optical amplification laser source in response to each laser pulse shot, (2) models retention of energy in the optical amplifier after laser pulse shots, and (3) models buildup of energy in the optical amplifier between laser pulse shots. 24 . The apparatus of claim 1 wherein the laser energy model models available laser energy for laser pulse shots at time intervals in a range between 10 nanoseconds to 100 nanoseconds. 25 . The