An integrated circuit assembly may include an integrated circuit having a plurality of programmable logic sectors and an interposer circuit positioned adjacent to the integrated circuit. The interposer circuit may include at least one voltage regulator that distributes a voltage to at least one of the plurality of programmable logic sectors and at least one thermal sensor that measures a temperature of the at least one of the plurality of programmable logic sectors.

A routing structure is disclosed. A first wiring line coupled to a programming access device and a routing block driver and receiver enabling device and a second wiring line coupled to a programming access device and a routing block driver and receiver enabling device. An insulator-metal-transistor device that includes a top electrode, a middle electrode and a bottom electrode, coupled at the intersection of the first wiring line and the second wiring line.

The invention relates to a digital isolator comprising a logic module (20) for receiving an input signal D, and providing command signals (41, 42) to sawtooth modulators. A first sawtooth modulator provides a first sawtooth signal at a node A1 comprising a fast rising edge triggered by a rising edge of a control signal, followed by a slow falling edge, when D equals 1 and comprises a fast falling edge triggered by a rising edge of a control signal, followed by a slow rising edge, when D equals 0. A second sawtooth modulator provides a second sawtooth signal at node A2, inverted with respect to first sawtooth signal. Isolation capacitors (61, 62) are connected to nodes A1 and A2 and are used as isolation barrier and as part of a high-pass filter together with dipoles Z1 and Z2. Threshold comparators (121, 122) provide the output signals S and R. Based on these S and R output signals, the input signal D referred to ground G1 can be regenerated versus a ground G2 using for example SR logic gate, low pass filters or peak detectors.

Various embodiments relate to a transmit driver circuit, including: a first node connected to a first differential output; a first transistor connected in series with a first resistor, wherein the series connected first transistor and first resistor are connected between a source voltage and the first node; a second transistor connected in series with a second resistor, wherein the series connected second transistor and second resistor are connected between the first node and a ground; a second node connected to a second differential output; a third transistor connected in series with a third resistor, wherein the series connected third transistor and third resistor are connected between the source voltage and the second node; a fourth transistor connected in series with a fourth resistor, wherein the series connected fourth transistor and fourth resistor are connected between the second node and the ground; a first differential input connected to the gate of the first transistor and the gate of the fourth transistor; and a second differential input connected to the gate of the second transistor and the gate of the third transistor, wherein the first transistor, second transistor, third transistor, and fourth transistor are NMOS transistors.

The disclosure provides a voltage adjust circuit. The voltage adjust circuit includes a buffer circuit, a bias circuit, a level shifter and a cross voltage limit circuit. The buffer circuit includes a plurality of pull-up transistors and a plurality of pull-down transistors. The pull-up transistors coupled in series between an output terminal of the circuit and a high voltage system terminal. The pull-down transistors coupled in series between the output terminal and a low voltage system terminal. The cross voltage limit circuit is configured to limit transient and static bias voltages across two terminals of the pull-up transistors or the pull-down transistors.

Systems and methods for routing communication among a plurality of devices are described. In an example, a controller can detect a communication initiated from a first device to a target device among a second device and a third device. The controller can identify the second device as the target device. The controller can, in response to identifying the second device as the target device, activate a direct communication path between the first device and the second device to allow the first device to communicate with the second device using direct communication mode. The controller can, in response to identifying the second device as the target device, activate redriver path between the first device and the third device to allow the first device to communicate with the third device using redriver mode.

A power domain change circuit includes an input circuit and an output circuit. The input circuit is suitable for operating in a first power domain and generating first and second intermediate processing signals. The output circuit is suitable for operating in a second power domain and generating a final output signal by averaging and combining transition jitter components of the first and second intermediate processing signals.

According to one embodiment, a bus buffer circuit includes an input buffer circuit that receives an input signal, and outputs a non-inversion input signal and an inversion input signal, a voltage conversion circuit that operates by a second power supply, performs voltage conversion on the non-inversion input signal and the inversion input signal input thereto, and outputs the signals as a voltage-converted non-inversion output signal and a voltage-converted inversion output signal, an output retaining circuit that retains the voltage-converted non-inversion output signal and the voltage-converted inversion output signal at a same potential level when an output enable signal is in a disable state, a determinator that determines whether these signals are at a same potential level, a three-state output buffer circuit that outputs the voltage-converted non-inversion output signal or the voltage-converted inversion output signal from an output terminal, and an output controller that sets the three-state output buffer circuit in an output disable state, when the voltage-converted non-inversion output signal and the voltage-converted inversion output signal are at a same potential level, on a basis of an outcome of the determinator. Therefore, it is possible to prevent a potential different from the actual bus signal from being temporarily output during an output state transition, in a case where the state is fixed to reduce the power consumption.

The invention relates to a signal isolation and conversion circuit and a control apparatus. The signal isolation and conversion circuit comprises a pulse signal generating circuit and an optical coupling complementary isolation circuit connected with the pulse signal generating circuit; the pulse signal generating circuit is used for receiving an input signal and converting the input signal into a pulse signal; the optical coupling complementary isolation circuit comprises at least two photocouplers, and the at least two photocouplers are switched on or off according to the pulse signal so as to transmit the pulse signal to the output end of the signal isolation and conversion circuit. By arranging the optical coupling complementary isolation circuit, the problems of transmission delay, transmission signal distortion and light attenuation and temperature drift of the light-emitting diode in the optocoupler are effectively solved, the timeliness of isolation signal transmission is improved.

A signal transmitting and receiving apparatus including: a first on-die termination circuit connected to a first pin through which a first signal is transmitted or received and, when enabled, the first on-die termination circuit is configured to provide a first termination resistance to a signal line connected to the first pin; a second on-die termination circuit connected to a second pin through which a second signal is transmitted or received and, when enabled, the second on-die termination circuit is configured to provide a second termination resistance to a signal line connected to the second pin; and an on-die termination control circuit configured to independently control an enable time and a disable time of each of the first on-die termination circuit and the second on-die termination circuit.