Abstract: A dynamically reconfigurable Light Detection and Ranging (LiDAR) system can generate improved ranging data one or more regions of three-dimensional (3D) images generated by the system. The images can be segmented, and global or local optical characteristics (e.g., power, illumination duration, bandwidth, framerate frequency) of the light can be modified to increase the 3D image quality for the segments of the image.

Abstract: The present disclosure is related to a sensing device. The sensing device includes a sensor, a memory, a processor, and two radio units. A first radio unit of the two radio units is configured for bidirectional communication with an external device using a first radio communication protocol. The bidirectional communication comprises receiving configuration data from the external device via a first radio signal from the external device. The second radio unit of the two radio units is configured for unidirectional communication with the external device using a second radio communication protocol. The unidirectional communication comprises the second radio unit transmitting a second radio signal to the external device. The second radio signal communicates data including one or more measurements obtained by the sensor.

Abstract: A single and dual path light detection and ranging (LiDAR) system can transmit and receive light through a silicon substrate backside of a photonic integrated circuit (PIC). The PIC can be interface with an electrical integrated circuit (EIC) using a front side that connects to the EIC using electrical contacts and a backside that faces away from the EIC. High density coupler elements (e.g., pixels, gratings) can emit and receive infrared light that propagates through the PIC layers and the backside towards objects to detection.

Abstract: A dual path configuration Integrated LiDAR architecture can contain a focal plane transmitter and a focal plane coherent receiver. The integrated LiDAR transmitter can contain an optical frequency chirp generator and a focal plane optical beam scanner with integrated driving electronics. The integrated LiDAR receiver architecture can be implemented with per-pixel coherent detection and amplification.

Abstract: A dynamically reconfigurable Light Detection and Ranging (LiDAR) system can generate improved ranging data one or more regions of three-dimensional (3D) images generated by the system. The images can be segmented, and global or local optical characteristics (e.g., power, illumination duration, bandwidth, framerate frequency) of the light can be modified to increase the 3D image quality for the segments of the image.

Abstract: A medication packet bundle includes one or more beacons. Each beacon may transmit a signal representing an event related to patient compliance with a medication regimen, such as removal of a packet of medication from a bundle or opening of a packet. The transmitted beacon signals can be monitored and processed to track patient compliance and adherence.

Abstract: The present disclosure relates to a method that includes calculating a first frequency drift associated with an oscillator at a current temperature; based on the calculation, generating a first signal indicative of temperature compensation data; generating a second signal indicative of packet data and a modulation scheme; using the first signal, the second signal, and a first predetermined signal to generate a first tuning signal; and using the first tuning signal to tune a first capacitor array coupled to the oscillator and a second tuning signal to tune a second capacitor array coupled to the oscillator such that (i) the oscillator generates a modulated RF signal indicative of the packet data and (ii) the modulated RF signal has a second frequency drift that is less than a threshold.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example system includes a sensor and a transceiver coupled to the sensor, the transceiver including: an oscillator circuit including a thin-film bulk acoustic resonator (FBAR), and an antenna. The system also includes a controller with a processor programmed to: broadcast, by the antenna, a first data packet on a wireless channel, where the first data packet is a first packet of a broadcast event; receive, at the antenna, a second data packet transmitted on the wireless channel, where the second data packet is a second packet of the broadcast event; and responsive to receiving the second data packet, perform an action associated with the broadcast event; responsive to the action, transmit, by the antenna, a third data packet on the wireless channel, where the third data packet is a third packet of the broadcast event.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example method includes generating, based on data, a data signal including one or more data packets, where each of the one or more data packets is a non-connectable and non-scannable data packet. The method further includes generating a plurality of RF signals of different frequencies using an oscillator circuit, directly modulating at least one of the RF signals, based on the data signal, to generate a modulated RF signal, amplifying the modulated RF signal, and broadcasting the amplified modulated RF signal on the wireless channel.

Abstract: The present disclosure relates to a method that includes calculating a first frequency drift associated with an oscillator at a current temperature; based on the calculation, generating a first signal indicative of temperature compensation data; generating a second signal indicative of packet data and a modulation scheme; using the first signal, the second signal, and a first predetermined signal to generate a first tuning signal; and using the first tuning signal to tune a first capacitor array coupled to the oscillator and a second tuning signal to tune a second capacitor array coupled to the oscillator such that (i) the oscillator generates a modulated RF signal indicative of the packet data and (ii) the modulated RF signal has a second frequency drift that is less than a threshold.

Abstract: A body-mountable light sensing device includes a photodiode configured to receive light from a portion of subsurface vasculature and electronics configured to operate the photodiode to measure the received light. The electronics include a photodiode voltage source configured to reverse bias the photodiode, a current mirror, and a sigma-delta modulator configured to generate a digital output related to the received light and having a high resolution while using low power. The digital output could be used to determine a pulse rate or other properties of blood in the portion of subsurface vasculature by detecting absorption of ambient light by blood in the portion of subsurface vasculature. Components of the body-mountable device could be embedded in a polymeric material configured for mounting to a surface of an eye. The digital output and/or related information could be wirelessly communicated by the body-mountable device.

Abstract: The present disclosure relates to a method that includes calculating a first frequency drift associated with an oscillator at a current temperature; based on the calculation, generating a first signal indicative of temperature compensation data; generating a second signal indicative of packet data and a modulation scheme; using the first signal, the second signal, and a first predetermined signal to generate a first tuning signal; and using the first tuning signal to tune a first capacitor array coupled to the oscillator and a second tuning signal to tune a second capacitor array coupled to the oscillator such that (i) the oscillator generates a modulated RF signal indicative of the packet data and (ii) the modulated RF signal has a second frequency drift that is less than a threshold.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example system includes a sensor and a transceiver coupled to the sensor, the transceiver including: an oscillator circuit including a thin-film bulk acoustic resonator (FBAR), and an antenna. The system also includes a controller with a processor programmed to: broadcast, by the antenna, a first data packet on a wireless channel, where the first data packet is a first packet of a broadcast event; receive, at the antenna, a second data packet transmitted on the wireless channel, where the second data packet is a second packet of the broadcast event; and responsive to receiving the second data packet, perform an action associated with the broadcast event; responsive to the action, transmit, by the antenna, a third data packet on the wireless channel, where the third data packet is a third packet of the broadcast event.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example system includes a sensor and a transceiver coupled to the sensor, the transceiver including: an oscillator circuit including a thin-film bulk acoustic resonator (FBAR), and an antenna. The system also includes a controller with a processor programmed to: broadcast, by the antenna, a first data packet on a wireless channel, where the first data packet is a first packet of a broadcast event; receive, at the antenna, a second data packet transmitted on the wireless channel, where the second data packet is a second packet of the broadcast event; and responsive to receiving the second data packet, perform an action associated with the broadcast event; responsive to the action, transmit, by the antenna, a third data packet on the wireless channel, where the third data packet is a third packet of the broadcast event.

Abstract: Methods and systems described herein relate to broadcasting an advertisement event on a wireless channel. An example method includes generating, based on data, a data signal including one or more data packets, where each of the one or more data packets is a non-connectable and non-scannable data packet; generating an RF signal using an oscillator circuit; directly modulating the RF signal, based on the data signal, to generate a modulated RF signal; amplifying the modulated RF signal; broadcasting the amplified modulated RF signal on the wireless channel, where the amplified modulated RF signal is associated with the advertisement event.

Abstract: An eye-mountable device includes an image sensor situated in a polymeric material configured to be mounted to a surface of an eye. The image sensor can be disposed on a substrate at least partially embedded in the polymeric material. The image sensor can include a photo-sensitive area occupied by a plurality of photo-sensitive elements. The photo-sensitive area is illuminated by light entering a non-focusing aperture in an opaque screen. The non-focusing aperture can be smaller than the photo-sensitive area such that each of the photo-sensitive elements receives light entering the non-focusing aperture from a respective direction. The direction-specific measurements of received light obtained by the multiple photo-sensitive elements can thereby be used to form an image.

Abstract: Techniques and mechanisms for determining a direction of gaze by a user of an eye-mountable device. In an embodiment, the eye-mountable device includes a first circuit and a second circuit, each comprising a respective photodiode. The second circuit is configured to provide a light response profile that is more linear than a light response profile provided by the first circuit. Light sensing by the first circuit results in generation of a first signal indicating a level of ambient light in a surrounding environment. Other light sensing by the second circuit results in a second signal being generated. A direction of gaze by a cornea of the user is detected based at least in part on the first signal and the second signal. In another embodiment, the first signal is provided to configure the second circuit.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example method includes generating, based on data, a data signal including one or more data packets, where each of the one or more data packets is a non-connectable and non-scannable data packet. The method further includes generating a plurality of RF signals of different frequencies using an oscillator circuit, directly modulating at least one of the RF signals, based on the data signal, to generate a modulated RF signal, amplifying the modulated RF signal, and broadcasting the amplified modulated RF signal on the wireless channel.

Abstract: A body-mountable light sensing device includes a photodiode configured to receive light from a portion of subsurface vasculature and electronics configured to operate the photodiode to measure the received light. The electronics include a photodiode voltage source configured to reverse bias the photodiode, a current mirror, and a sigma-delta modulator configured to generate a digital output related to the received light and having a high resolution while using low power. The digital output could be used to determine a pulse rate or other properties of blood in the portion of subsurface vasculature by detecting absorption of ambient light by blood in the portion of subsurface vasculature. Components of the body-mountable device could be embedded in a polymeric material configured for mounting to a surface of an eye. The digital output and/or related information could be wirelessly communicated by the body-mountable device.

Abstract: Methods and systems described herein relate to broadcasting on a wireless channel. An example system includes a sensor and a transceiver coupled to the sensor, the transceiver including: an oscillator circuit including a thin-film bulk acoustic resonator (FBAR), and an antenna. The system also includes a controller with a processor programmed to: broadcast, by the antenna, a first data packet on a wireless channel, where the first data packet is a first packet of a broadcast event; receive, at the antenna, a second data packet transmitted on the wireless channel, where the second data packet is a second packet of the broadcast event; and responsive to receiving the second data packet, perform an action associated with the broadcast event; responsive to the action, transmit, by the antenna, a third data packet on the wireless channel, where the third data packet is a third packet of the broadcast event.