Provided are methods for detecting objects within a vehicle. The methods can include emitting at least one auditory signal within the vehicle during at least one first time interval; measuring a second auditory signal emitted by an object within the vehicle during the second time interval subsequent to the at least one first time interval, where the emission of the second auditory signal is caused by the emission of the least one first auditory signal; determining a location of the object within the vehicle based on the measurement of the second auditory signal; and generating an alert to a user indicating the location of that object. Systems and computer program products are also provided.

An apparatus, method, and computer-readable medium for high ping rate depth sounding. The apparatus may cause transmission of a first sonar beam having a first frequency and transmission of a second sonar beam having a second frequency with a transducer assembly. The transducer assembly maybe configured to transmit the first sonar beam and the second sonar beam into the underwater environment. The apparatus may receive sonar return data from the transducer assembly beginning either simultaneously with transmission of the first sonar beam or prior to transmission of the second sonar beam. The apparatus may further determine, based on sonar return data acquired after transmission of both the first sonar beam and the second sonar beam, that the sonar return data corresponds to the first sonar beam by determining that the sonar return data comprises the first frequency.

An apparatus, method, and computer-readable medium for high ping rate depth sounding. The apparatus may cause transmission of a first sonar beam having a first frequency and transmission of a second sonar beam having a second frequency with a transducer assembly. The transducer assembly maybe configured to transmit the first sonar beam and the second sonar beam into the underwater environment. The apparatus may receive sonar return data from the transducer assembly beginning either simultaneously with transmission of the first sonar beam or prior to transmission of the second sonar beam. The apparatus may further determine, based on sonar return data acquired after transmission of both the first sonar beam and the second sonar beam, that the sonar return data corresponds to the first sonar beam by determining that the sonar return data comprises the first frequency.

An object detector includes: a triangulation calculation unit that performs triangulation calculation for detecting a location of an object based on first distance information calculated based on direct waves in which transmitted waves transmitted from a first transmission and reception unit are reflected by an object and received by the first transmission and reception unit, and second distance information calculated based on indirect waves in which transmitted waves transmitted from a second transmission and reception unit arranged in a location different from the first transmission and reception unit are reflected by an object and received by the first transmission and reception unit; and a prohibition processing unit that prohibits triangulation calculation when a difference between first velocity information indicating a velocity of an object calculated based on the direct waves and second velocity information indicating a velocity of an object calculated based on the indirect waves exceeds a predetermined range.

Techniques for presence-detection devices to detect movement of a person in an environment by emitting ultrasonic signals using a loudspeaker that is concurrently outputting audible sound. To detect movement by the person, the devices characterize the change in the frequency, or the Doppler shift, of the reflections of the ultrasonic signals off the person caused by the movement of the person. However, when a loudspeaker plays audible sound while emitting the ultrasonic signal, audio signals generated by microphones of the devices include distortions caused by the loudspeaker. These distortions can be interpreted by the presence-detection devices as indicating movement of a person when there is no movement, or as indicating lack of movement when a user is moving. The techniques include processing audio signals to remove distortions to more accurately identify changes in the frequency of the reflections of the ultrasonic signals caused by the movement of the person.

An object detection system includes a plurality of object detection devices disposed at predetermined intervals. Each object detection device includes a transmission unit configured to transmit a transmission wave on which frequency modulation based on chirp signals that change in a frequency pattern different from that of an initial signal is performed subsequently to frequency modulation based on the initial signal so as to be in a mode different from those in the object detection devices including the adjacent object detection devices, a reception unit configured to receive a reception wave as the transmission wave returned in response to reflection on an object, and a detection processing unit configured to detect information related to the object based on information acquired as a result of transmission and reception of the transmission wave and the reception wave.

A device and method for reducing noise of an external measurement sensor of mobility, including a storage unit that stores measurement values of an external measurement sensor of mobility including an ultrasonic sensor measuring distance values between the mobility and an object outside the mobility; and an operation unit that generates a plurality of functions capable of being derived from the measurement values stored in the storage unit, derives a final function having the most measurement values within a first range, among the plurality of functions, derives an estimated value that is an expected value of the measurement value through the final function, and selects a candidate final value that is the closest to the estimated value within a second range, among actual measurement values at a time point corresponding to the estimated value, as a final value.

A device and method for reducing noise of an external measurement sensor of mobility, including a storage unit that stores measurement values of an external measurement sensor of mobility including an ultrasonic sensor measuring distance values between the mobility and an object outside the mobility; and an operation unit that generates a plurality of functions capable of being derived from the measurement values stored in the storage unit, derives a final function having the most measurement values within a first range, among the plurality of functions, derives an estimated value that is an expected value of the measurement value through the final function, and selects a candidate final value that is the closest to the estimated value within a second range, among actual measurement values at a time point corresponding to the estimated value, as a final value.

Techniques for calibrating presence-detection devices to account for various factors that can affect the presence-detection devices' ability to detect movement. Presence-detection devices may detect movement of a person in an environment by emitting ultrasonic signals into the environment, and characterizing the change in the frequency, or the Doppler shift, of the reflections of the ultrasonic signals off the person caused by the movement of the person. However, factors such as environmental acoustic conditions, noise sources, etc., may affect the ability of the presence-detection devices to detect movement. To calibrate for these factors, the presence-detection devices may use a loudspeaker to emit an ultrasonic sweep signal that spans different frequencies in an ultrasonic frequency range. The presence-detection devices may generate audio data using a microphone that represents the ultrasonic sweep signal, and analyze that audio data to determine an optimal frequency range and/or transmission power for subsequent ultrasonic signal transmissions.

An ultrasonic-based person detection method. The method comprising the steps of: (a) emitting, from an emitter, an ultrasonic signal, the ultrasonic signal including a component at a first frequency; (b) receiving reflections of the ultrasonic signal, the received signal including components at frequencies greater than and less than the first frequency; (c) determining a difference between an upper portion of the received signal containing a frequency higher than the first frequency, and a lower portion of the received signal containing a frequency lower than the first frequency; and (d) determining, based on the difference between the upper portion and the lower portion, whether a person is present.