Abstract: A synaptic time-multiplexed (STM) neuromorphic network includes a neural fabric that includes nodes and switches to define inter-nodal connections between selected nodes of the neural fabric. The STM neuromorphic network further includes a neuromorphic controller to form subsets of a set of the inter-nodal connections representing a fully connected neural network. Each subset is formed during a different time slot of a plurality of time slots of a time multiplexing cycle of the STM neuromorphic network. In combination, the inter-nodal connection subsets implement the fully connected neural network. A method of synaptic time multiplexing a neuromorphic network includes providing the neural fabric and forming the subsets of the set of inter-nodal connections.

Abstract: A delay circuit includes a first flip flop (FF), a transistor connected to the FF, a first resistor capacitor circuit (RCC) coupled to the transistor and between a voltage and a ground, a first comparator for comparing an output of the first RCC and a voltage reference, gate logic coupled to the input line and to an output of the first FF and to a second FF, a second transistor coupled to the second FF, a second RCC coupled to the second transistor and between the voltage and ground, a second comparator for comparing an output of the second RCC and the voltage reference and coupled to the first FF, and output logic coupled to the first and second comparators.

Abstract: A synaptic time-multiplexed (STM) neuromorphic network includes a neural fabric that includes nodes and switches to define inter-nodal connections between selected nodes of the neural fabric. The STM neuromorphic network further includes a neuromorphic controller to form subsets of a set of the inter-nodal connections representing a fully connected neural network. Each subset is formed during a different time slot of a plurality of time slots of a time multiplexing cycle of the STM neuromorphic network. In combination, the inter-nodal connection subsets implement the fully connected neural network. A method of synaptic time multiplexing a neuromorphic network includes providing the neural fabric and forming the subsets of the set of inter-nodal connections.

Abstract: A system, circuit and methods for target detection from hyper-spectral image data are disclosed. Filter coefficients are determined using a modified constrained energy minimization (CEM) method. The modified CEM method can operate on a circuit operable to perform constrained linear programming optimization. A filter comprising the filter coefficients is applied to a plurality of pixels of the hyper-spectral image data to form CEM values for the pixels, and one or more target pixels are identified from the CEM values. The process may be repeated to enhance target recognition by using filter coefficients determined by excluding the identified target pixels from the hyper-spectral image data.

Abstract: A circuit for generating chaotic signals implemented using heterojunction bipolar transistors (HBTs) and utilized in low probability intercept communications. The HBT chaotic circuit generates truly random analog signals in the GHz range that are non-repeating and deterministic and may not be replicated by preloading a predetermined sequence. A fully differential autonomous chaotic circuit outputs two pairs of chaotic signals to be used in a communication system. As it is impossible to generate identical chaotic signals at the transmitter and receiver sites, the receiver itself sends the chaotic signal to be used for encoding to the transmitter. The receiver includes a chaotic signal generator and digitizes, upconverts, and transmits the generated chaotic signal to the transmitter. The transmitter uses the received chaotic signal to code data to be transmitted. The receiver decodes the transmitted data that is encoded by the chaotic signal to retrieve the transmitted data.

Abstract: A system, circuit and methods for target detection from hyper-spectral image data are disclosed. Filter coefficients are determined using a modified constrained energy minimization (CEM) method. The modified CEM method can operate on a circuit operable to perform constrained linear programming optimization. A filter comprising the filter coefficients is applied to a plurality of pixels of the hyper-spectral image data to form CEM values for the pixels, and one or more target pixels are identified from the CEM values. The process may be repeated to enhance target recognition by using filter coefficients determined by excluding the identified target pixels from the hyper-spectral image data.

Abstract: A circuit for generating chaotic signals implemented using heterojunction bipolar transistors (HBTs) and utilized in low probability intercept communications. The HBT chaotic circuit generates truly random analog signals in the GHz range that are non-repeating and deterministic and may not be replicated by preloading a predetermined sequence. A fully differential autonomous chaotic circuit outputs two pairs of chaotic signals to be used in a communication system. As it is impossible to generate identical chaotic signals at the transmitter and receiver sites, the receiver itself sends the chaotic signal to be used for encoding to the transmitter. The receiver includes a chaotic signal generator and digitizes, upconverts, and transmits the generated chaotic signal to the transmitter. The transmitter uses the received chaotic signal to code data to be transmitted. The receiver decodes the transmitted data that is encoded by the chaotic signal to retrieve the transmitted data.

Abstract: A pulse circuit to solve a system of differential equations in the pulse domain based on analog or inputs or time-encoded pulse inputs. Intrinsically linear 1-bit digital to analog converters are used as feedback elements within circuits implementing solutions to a differential equation or to a system of differential equations. The circuits may be used to implement filters. While the input to the circuit may be an analog signal, the internal signals of the circuit are time-encoded current or voltage pulses. Output of the circuit is a time-encoded pulse or a series of time-encoded pulses from which an analog output may be recovered by time decoding.

Abstract: In one embodiment of the present invention, an amplifier circuit is provided which includes a predistorter coupled to a power amplifier. An error detector is coupled to the signal input of the predistorter via a delay circuit and to the power amplifier output. The error detector output is coupled to a delta-sigma modulator and the output of the delta-sigma is coupled to the control input of the predistorter. The predistorter may be constructed to provide an output selected from a set of output characteristic curves, in response to a control signal at the control input. The control input of the predistorter may be a multi-bit discrete input, which may be a binary input, such as for example, a three bit binary input.

Abstract: A memory module for storing data. The memory module includes: a circuit board that has a plurality of electrical terminals; a volatile memory device that is mounted on the circuit board; and a radio transmitter that is mounted on the circuit board. The radio transmitter is operable to transmit information.

Abstract: One embodiment of the present invention provides a system for generating a pseudo-random non-periodic digital sequence. The system operates by receiving a non-periodic signal at a data input of a flip-flop. This non-periodic signal is sampled at the flip-flop with a clock signal, thereby producing the pseudo-random non-periodic digital sequence at the output of the flip-flop.

Abstract: One embodiment of the present invention provides a system for generating a pseudo-random non-periodic digital sequence. The system operates by receiving a non-periodic signal at a data input of a flip-flop. This non-periodic signal is sampled at the flip-flop with a clock signal, thereby producing the pseudo-random non-periodic digital sequence at the output of the flip-flop.

Abstract: An improved signal buffer configuration has been developed for transmitting communication signals across line traces between ICs on a printed circuit board, printed wiring board, multi-chip module, integrated circuit carrier or package, or other interconnect substrate. For example, in some realizations, multiple ICs having mismatched input and output impedances are mounted on an printed circuit board and communicate with each other via line traces. A signal buffer IC is placed in-line with the connecting line trace. The buffer is sized to fit within the pitch spacing of the line trace and contains an input impedance control circuit and an output impedance control circuit. These impedance control circuits are adapted to receive a control signal to set the input and output impedances of the buffer to correspond to the impedances of the connecting line traces. In this manner, the impedances between the ICs connected by this line trace are effectively matched and transmission line errors between them are reduced.

Abstract: An improved signal buffer configuration has been developed for transmitting communication signals across line traces between ICs on a printed circuit board, printed wiring board, multi-chip module, integrated circuit carrier or package, or other interconnect substrate. For example, in some realizations, multiple ICs having mismatched input and output impedances are mounted on an printed circuit board and communicate with each other via line traces. A signal buffer IC is placed in-line with the connecting line trace. The buffer is sized to fit within the pitch spacing of the line trace and contains an input impedance control circuit and an output impedance control circuit. These impedance control circuits are adapted to receive a control signal to set the input and output impedances of the buffer to correspond to the impedances of the connecting line traces. In this manner, the impedances between the ICs connected by this line trace are effectively matched and transmission line errors between them are reduced.

Abstract: One embodiment of the present invention provides a system that facilitates communicating between integrated circuit devices within a computing system. The system includes integrated circuit devices with an individual radio port coupled to each integrated circuit device. Each radio port includes a transmitting mechanism that is configured to generate radio signals in response to commands from the integrated circuit device. An antenna is coupled to the radio port to transmit the radio signal generated by the transmitting mechanism and to detect a response to the radio signal. Each radio port also includes a receiving mechanism to receive responses from the antenna and pass the responses to the integrated circuit device.

Abstract: One embodiment of the present invention provides a system that uses a non-periodic signal to modulate the period of a clock signal. The system includes a latch with a latch input, a latch output and a clock input. Asserting the clock input of the latch causes a data value at the latch input to be stored into the latch, and to thereby appear at the latch output. The system also includes an inverting delay circuit that receives the clock signal from the latch output and generates an inverted and delayed clock signal, which feeds back into the input of the latch. The clock input of the latch is coupled to the non-periodic signal, so that the non-periodic signal is used to latch the inverted and delayed clock signal, so that the clock signal changes at a non-periodic interval. In one embodiment of the present invention, the inverting delay circuit includes a chain of an odd number of inverters.