A method and device for determining the distance between an airborne receiver and a stationary ground transmitter are disclosed. A digital terrain model is implemented to determine a range of distance values containing the transmitter. A receiver distance is found and, with the range of values, a plurality of theoretical distances is calculated, to each of which a corresponding azimuth angle and elevation angle are associated. The thus calculated azimuth and elevation angles are compared to the measured azimuth and elevation angles of the line of sight under which the receiver observes the transmitter.

Described herein are systems and methods for improving detection of a return signal in a light ranging and detection system. The system comprises a transmitter and a receiver. A first sequence of pulses may be encoded with an anti-spoof signature and transmitted in a laser beam. A return signal, comprising a second sequence of pulses, may be received by the receiver and the anti-spoof signature extracted from the second sequence of pulses. If based on the extraction, the first and second sequences of pulses match, the receiver outputs return signal data. If based on the extraction, the first and second sequence of pulses do not match, the return signal is disregarded. The system may dynamically change the anti-spoofing signature for subsequent sequences of pulses. Additionally, the first sequence of pulses may be randomized relative to a prior sequence of pulses.

Described herein are systems and methods for improving detection of a return signal in a light ranging and detection system. The system comprises a transmitter and a receiver. A first sequence of pulses may be encoded with an anti-spoof signature and transmitted in a laser beam. A return signal, comprising a second sequence of pulses, may be received by the receiver and the anti-spoof signature extracted from the second sequence of pulses. If based on the extraction, the first and second sequences of pulses match, the receiver outputs return signal data. If based on the extraction, the first and second sequence of pulses do not match, the return signal is disregarded. The system may dynamically change the anti-spoofing signature for subsequent sequences of pulses. Additionally, the first sequence of pulses may be randomized relative to a prior sequence of pulses.

Systems, methods, and computer-readable media are disclosed for a systems and methods for pre-blinding light detectors. An example method may include sending, by a processor of a LIDAR system and at a first time, a signal to a light source of the LIDAR system, the signal causing the light source to provide a light input to a photodetector of the LIDAR system, wherein the light input to the photodetector causes the photodetector to initiate a recovery period. The example method may also include emitting, by a laser of the LIDAR system, a first light pulse into an environment at a second time. The example method may also include receiving, by the photodetector, return light associated with the first light pulse from an object in the environment, the return light reaching the photodetector at a third time, the third time being after the photodetector has ended the recovery period.

A LIDAR system includes a light source configured to output light. A portion of the light is included in a LIDAR signal that travels a LIDAR path from the light source to an object located outside of the LIDAR system and from the object to a filter and from the filter to a processing unit. The processing unit is configured to convert optical signals that include the LIDAR signal to electrical signals. A portion of the light is also included in one or more misdirected signals. Each of the misdirected signals travels a different misdirected path from the light source to the filter. Each of the misdirected paths is a different path from the LIDAR path. The system also includes a filter being configured to filter out the LIDAR signal from the misdirected signals. The system also includes electronics that generate LIDAR data from the electrical signals.

A LIDAR system includes a light source configured to output light. A portion of the light is included in a LIDAR signal that travels a LIDAR path from the light source to an object located outside of the LIDAR system and from the object to a filter and from the filter to a processing unit. The processing unit is configured to convert optical signals that include the LIDAR signal to electrical signals. A portion of the light is also included in one or more misdirected signals. Each of the misdirected signals travels a different misdirected path from the light source to the filter. Each of the misdirected paths is a different path from the LIDAR path. The system also includes a filter being configured to filter out the LIDAR signal from the misdirected signals. The system also includes electronics that generate LIDAR data from the electrical signals.

An electro-optical distance measurement method includes: a light emitting step of switchably outputting a first distance measuring light and a second distance measuring light; a photodetection step of receiving a first reflected distance measuring light and a second reflected distance measuring light; an arithmetic step of frequency-converting a photodetection signal to generate a first difference frequency signal and a second difference frequency signal; and a determining step of determining whether identification information indicating a host device is included in the photodetection signal, wherein the light emitting step involves driving a light emitting element so that the identification information is included in a light emission signal, and the arithmetic step involves calculating the distance value when it is determined in the determining step that the identification information is included in the photodetection signal.

A LIDAR sensor, including a window, at least one first group and one second group of electrical conductors, and a detection circuit. The window is a light exit and entry interface of the LIDAR sensor. Each of the groups includes a first conductor and a second conductor, which are situated on and/or within the window, electrically insulated from one another, form a capacitive sensor, and are electrically connected to the detection circuit. The first and second groups are situated at positions which deviate from one another. The detection circuit generates an electrical field between the respective first conductors and second conductors of the respective groups to detect a change in the electrical field as a result of an object in close range of the window, ascertain a position of the object within the surface of the window, and provide a piece of information about the position of the object.

A LIDAR sensor, including a window, at least one first group and one second group of electrical conductors, and a detection circuit. The window is a light exit and entry interface of the LIDAR sensor. Each of the groups includes a first conductor and a second conductor, which are situated on and/or within the window, electrically insulated from one another, form a capacitive sensor, and are electrically connected to the detection circuit. The first and second groups are situated at positions which deviate from one another. The detection circuit generates an electrical field between the respective first conductors and second conductors of the respective groups to detect a change in the electrical field as a result of an object in close range of the window, ascertain a position of the object within the surface of the window, and provide a piece of information about the position of the object.

A method is disclosed for determining and compensating a proportion of stray light of a measuring beam of a 3D laser scanner by which a 3D point cloud of an object to be detected can be generated via phase-based distance measurement including a first sequence by which first parameters of a proportion of stray light can be determined independently of the 3D point cloud and/or a second sequence by which second parameters of the proportion of stray light dependent on the generated 3D point cloud and a step can be determined. The proportion of stray light can be compensated as a function of the first parameters and/or the second parameters.