One aspect of the present disclosure provides a terahertz-wave detector including a semiconductor substrate, an active element formed on the semiconductor substrate and a first resistive portion electrically connected in parallel with the active element.

A reservoir computing system comprising an input layer configured to receive input data from a signal propagation channel and to convert the input data into fixed input values, a reservoir configured to receive the fixed input values and generate a set of trained output values, and an output layer configured to receive the set of trained output values and generate a probability distribution based on the set of trained output values. The reservoir is comprised of a plurality of integrated oscillator components coupled in a fixed, random network, wherein each of the oscillator components is comprised of a device characterized by a current-voltage curve that comprises a region of non-linear behavior, such as a negative differential resistance (NDR) behavior.

A reservoir computing system comprising an input layer configured to receive input data from a signal propagation channel and to convert the input data into fixed input values, a reservoir configured to receive the fixed input values and generate a set of trained output values, and an output layer configured to receive the set of trained output values and generate a probability distribution based on the set of trained output values. The reservoir is comprised of a plurality of integrated oscillator components coupled in a fixed, random network, wherein each of the oscillator components is comprised of a device characterized by a current-voltage curve that comprises a region of non-linear behavior, such as a negative differential resistance (NDR) behavior.

A computing reservoir comprised of a plurality of oscillator components configured to receive input data and produce one or more output signals, and a feedback loop coupled to an output of the network, wherein the feedback loop is comprised of circuitry configured to establish and maintain an optimal operating point of the network based upon the output of the network.

A switching inductor device having a first port and a second port includes a first inductor and a second inductor with a switch circuit. The first inductor is coupled between the first port and the second port. The second inductor and the switch circuit are connected in series, and are coupled between the first port and the second port; the first inductor and the second inductor are connected in parallel when the switch circuit is turned on.

A switching inductor device having a first port and a second port includes a first inductor and a second inductor with a switch circuit. The first inductor is coupled between the first port and the second port. The second inductor and the switch circuit are connected in series, and are coupled between the first port and the second port; the first inductor and the second inductor are connected in parallel when the switch circuit is turned on.

One aspect of the present disclosure provides a terahertz-wave detector including a semiconductor substrate, an active element formed on the semiconductor substrate and a first resistive portion electrically connected in parallel with the active element.

Embodiments may relate to a structure to be used in a neural network. A first column and a second column, both of which are to couple with a substrate. A capacitor structure may be electrically coupled with the first column. An insulator-metal transition (IMT) structure may be coupled with the first column such that the capacitor structure is electrically positioned between the IMT structure and the first column. A resistor structure may further be electrically coupled with the IMT structure and the second column such that the resistor structure is electrically positioned between the second column and the IMT structure. Other embodiments may be described or claimed.

In one form, an oscillator includes an oscillator core circuit and a dynamic gain control circuit. The oscillator core circuit is for connection to a frequency reference element and provides a first clock signal using a negative gain element having a gain determined by a gain control signal. The dynamic gain control circuit is coupled to the oscillator core circuit for calibrating the gain control signal to a startup value based on oscillations reaching a first threshold during a startup state, and calibrating the gain control signal to a steady-state value based on oscillations falling to a second threshold after an end of the startup state and before entering a steady state. The first threshold is higher than the second threshold. The dynamic gain control circuit operates the oscillator core circuit during the steady state using the steady-state value.

A switching inductor device having a first port and a second port includes a first inductor and a second inductor with a switch circuit. The first inductor is coupled between the first port and the second port. The second inductor and the switch circuit are connected in series, and are coupled between the first port and the second port; the first inductor and the second inductor are connected in parallel when the switch circuit is turned on.