Abstract: A diffractive optical element (DOE) is designed to implement both a collimation function with respect to an input divergent beam and a beam shaping function with respect to an output divergent beam. The phase designs of the collimation function and the beam shaping function are independently produced in the phase domain. These phase designs are then combined using a phase angle addition of the individual functions and wrapped between 0 and 2? radians. The diffractive surface of the DOE is then defined from the wrapped phase angle addition of the individual functions.

Abstract: The present disclosure includes a method that includes generating a decoded output signal that corresponds to reflected light received by a plurality of single photon avalanche diodes (SPAD) by removing ambient light from a plurality of SPAD array output signals. The removing of ambient light including synchronizing the plurality of SPAD array output signals by using a plurality of parallel time to digital converters, each time to digital converter outputting a synchronized SPAD array output signal, determining a plurality of flexible thresholds for each one of the synchronized SPAD array output signals, comparing current data on the synchronized SPAD array output signals with the respective ones of the flexible threshold in a filter, and outputting the first output signal.

Abstract: A method can be used to manufacture a charge storage cell with a first trench and a second trench in a substrate material. The first trench is filled with a doped material. The second trench is filled with a second trench material. The method includes causing the dopant to diffuse from the first trench to thereby provide a doped region adjacent to the first trench. The material from the first and second trenches is removed and at least one of the trenches is filled with a capacitive deep trench isolation material to provide capacitive deep trench isolation.

Abstract: An electronic device includes at least one photodetection block, where the at least one photodetection block includes a plurality of macropixels arranged into an array. Each macropixel includes an array of photodiodes, with logic circuitry coupled to outputs of the array of photodiodes and configured to generate a detection signal as a function of logically combining the outputs of the array of photodiodes. Each macropixel has associated therewith selection circuitry configured to selectively pass the detection signal to output combining logic or to output combining logic of at least one neighboring macropixel of the plurality thereof. The output combining logic has inputs coupled to the selection circuitry and to the selection circuitry of the at least one neighboring macropixel, and is configured to generate an output detection signal as a function of logically combining outputs of the selection circuitry and the selection circuitry of the at least one neighboring macropixel.

Abstract: An apparatus includes a camera module configured to generate at least one image and a ToF SPAD based range detecting module configured to generate at least one distance determination to an object within a field of view of the camera module. A processor receives the at least one image from the camera module output and receives the at least one distance determination from the ToF SPAD based range detecting module. This data is processed by the processor to determine a depth map.

Abstract: Photoluminescence from a sample detector is detected using an array of photo-sensitive detectors. At least one first photo-sensitive detector of the array is provided with a first type of linear polarization filter and at least one second photo-sensitive detector is provided with a second type of linear polarization filter. The first type of linear polarization filter has a plane of polarization which is at angled with respect to a plane of polarization of said second type of polarization filter.

Abstract: An electronic device disclosed herein includes a first integrated circuit die having formed therein photodiodes and readout circuitry for the photodiodes, with the readout circuitry including output pads exposed on a surface of the first integrated circuit die. A second integrated circuit die has formed therein storage capacitor structures for the photodiodes and digital circuitry for performing image processing on data stored in the storage capacitor structures, with the storage capacitor structures including input pads exposed on a surface of the second integrated circuit die. The first and second integrated circuit die are in a face to face arrangement such that the output pads of the first integrated circuit die face the input pads of the second integrated circuit die. An interconnect couples the output pads of the first integrated circuit die to the input pads of the second integrated circuit die.

Abstract: An embodiment circuit includes a first voltage-controlled delay line (VCDL), a second VCDL, and a first flip-flop. The first VCDL includes a first input terminal configured to receive a first input voltage, and a second input terminal configured to receive a clock signal. The second VCDL includes a first input terminal configured to receive a second input voltage, and a second input terminal configured to receive the clock signal. The first flip-flop includes a reset pin coupled to an output terminal of the first VCDL, and a clock pin coupled to an output terminal of the second VCDL.

Abstract: A single photon avalanche diode based apparatus comprising: at least one array of single photon avalanche diodes configured to receive light generated externally to the apparatus, wherein the at least one array is configurable to be sub-divided into a plurality of sub-arrays, each sub-array able to receive a separate free space light communication channel; and a receiver configured to receive the output from each sub-array and output data based on the received plurality of sub-array separate free space light communication channel.

Abstract: An oven may include a housing having a cooking receptacle configured to hold content therein, a heating element carried by the housing and configured to heat the content, and a proximity detector carried by the housing in the cooking receptacle and configured to detect surface movement of the content. The proximity detector may include at least one SPAD.

Abstract: An input device may include an image sensor having an imaging surface comprising that includes an array of pixels, and an optical waveguide layer carried by the imaging surface and having an exposed user surface and a first refractive index associated therewith. The input device may also include a substrate between the optical waveguide layer and the image sensor and having a second refractive index associated therewith that is lower than first refractive index. A collimation layer may be between the image sensor and the substrate. A light source may be configured to transmit light into the optical waveguide so that the light therein undergoes a total internal reflection. The optical waveguide may be being adjacent the imaging surface so that an object brought into contact with the exposed user surface disturbs the total internal reflection results resulting in an image pattern on the imaging surface.

Abstract: An embodiment device includes an optical source configured to generate an optical carrier including an optical pulse train; and a modulator configured to modulate an amplitude of the optical pulse train, based on data generated by a data source, to produce a modulated optical signal.

Abstract: A driver circuit is configured to pass a current. The circuit includes a first transistor connected in series with the laser diode, and configured to regulate the current. A voltage regulator is configured to provide an input to a gate of the first transistor so as to regulate the current in dependence upon a regulator input and a feedback input at the voltage regulator.

Abstract: An electronic device includes a ranging light source and a reflected light detector. A logic circuit causes the ranging light source to emit ranging light at a target. Reflected light from the target is detected using the reflected light detector, with the reflected light being a portion of the ranging light that reflects from the target back toward the reflected light detector. An intensity of the reflected light is determined using the reflected light detector. A distance to the target is determined based upon time elapsed between activating the ranging light source and detecting the reflected ranging light. Reflectance of the target is calculated, based upon the intensity of the reflected light and the distance to the target.

Abstract: A time to digital converter (TDC) may include a sampling stage configured to sample an input signal based upon a plurality of timing signals having different respective phases, and provide a respective output for each of the different timing signals. A first synchronization stage may be configured to receive the outputs from the sampling stage, synchronize a first subset of the outputs to a first one of the plurality of timing signals, and synchronize a second subset of the outputs to a second one of the plurality of timing signals. A second synchronization stage may be configured to receive the synchronized outputs from the first synchronization stage, and synchronize all of the synchronized outputs from the first synchronization stage to the first one of the plurality of timing signals.

Abstract: A distance from an apparatus to at least one object is determined by generating a first signal and generating light modulated by the first signal to be emitted from the apparatus. Light reflected by the at least one object is detected using a Time-of-flight detector array, wherein each array element of the Time-of-flight detector array generates an output signal from a series of photon counts over a number of consecutive non-overlapping time periods. The output signals are compared to the first signal to determine at least one signal phase difference. From this at least one signal phase difference a distance from the apparatus to the at least one object is determined.

Abstract: A method for forming a molded proximity sensor with an optical resin lens and the structure formed thereby. A light sensor chip is placed on a substrate, such as a printed circuit board, and a diode, such as a laser diode, is positioned on top of the light sensor chip and electrically connected to a bonding pad on the light sensor chip. Transparent, optical resin in liquid form is applied as a drop over the light sensor array on the light sensor chip as well as over the light-emitting diode. After the optical resin is cured, a molding compound is applied to an entire assembly, after which the assembly is polished to expose the lenses and have a top surface flush with the top surface of the molding compound.

Abstract: An optical electronic device may include a plurality of different optical sources, and a global shutter sensor including an array of global shutter pixels, with each global shutter pixel including a plurality of storage elements. A controller may be coupled to the plurality of optical sources and the global shutter sensor and configured to cause a first optical source to illuminate and a first storage element in each global shutter pixel to store optical data during a first integration period, cause a second optical source to illuminate and a second storage element in each global shutter pixel to store optical data during a second integration period, and output the stored optical data from the first and second storage elements of the global shutter pixels after the first and second integration periods.

Abstract: An embodiment circuit includes a diode having a first terminal coupled to a first reference voltage; a first controllable switch coupled between a second terminal of the diode and a second reference voltage; and a capacitive element having a first terminal coupled to the first reference voltage and a second terminal controllably coupled to the second terminal of the diode.

Abstract: An embodiment circuit includes a first source follower configured to be controlled by a voltage at a first node, a photodiode controllably coupled to the first node, and a bias transistor configured to be controlled by a bias voltage. The bias transistor has a first terminal coupled to an output of the first source follower. The circuit additionally includes a storage node controllably coupled to the output of the first source follower, and an amplifier controllably coupled between the storage node and an output line. Also included in the circuit is a controllable switching element configured to couple a second terminal of the bias transistor to a supply voltage in response to a pixel operating in a first mode, and to couple the second terminal of the bias transistor to the output line in response to the pixel operating in a second mode.