Described examples include a hybrid circuit having a component. The component has a first conductive element on a substrate having a configuration and having a first periphery and having an extension at the first periphery. The component also has a dielectric on the first conductive element. The component also has a second conductive element having the configuration on the dielectric that is proximate to and aligned with the first conductive element, and has a second periphery, the extension of the first conductive element extending past the second periphery.

Methods and apparatus are disclosed for communicating multiple logic states across a digital isolator. The digital isolator is a universal serial bus (USB) isolator in some embodiments. The digital isolator includes one or more single-bit data channels. Three or more logic states of information are transmitted across the single-bit data channel(s). The logic states are distinguished by a pulse sequence, and in particular a number of edges of the pulse sequence and a final value or final edge of the pulse sequence.

A digital isolator according to an embodiment includes a first electrode, a first insulating part, a second electrode, a second insulating part, and a first dielectric part. The first insulating part is located under the first electrode. The second electrode is located under the first insulating part. The second insulating part is located around the first electrode along a first plane perpendicular to a first direction. The first direction is from the second electrode toward the first electrode. The first dielectric part is located between the first electrode and the second insulating part in a second direction along the first plane. The first dielectric part contacts the first electrode. A relative dielectric constant of the first dielectric part is greater than a relative dielectric constant of the first insulating part.

LED drive control circuitry according to one embodiment outputs an LED drive control signal serving as driving a light emitting diode included in a photocoupler that performs insulation communication in synchronization with a reference clock signal. The LED drive control circuit includes a duty cycle changer that changes a duty cycle of the LED drive control signal in accordance with the reference clock signal and a signal synchronized with the reference clock signal.

A communication system has a galvanic isolation link coupling a first circuit to a second circuit. The first circuit transmits first data signals to the second circuit and receives second data signals from the second circuit in response to the first data signals. The data signals are transmitted in consecutive time slots of a determined time duration via the galvanic isolation link. The first data signals include polling signals transmitted from the first circuit to the second circuit during consecutive time slots, and on-demand access requests transmitted from the first circuit to the second circuit. The second data signals include status response signals transmitted from the second circuit to the first circuit in response to polling signals received from the first circuit, and access response signals transmitted from the second circuit to the first circuit in response to access requests received from the first circuit.

There is provided a semiconductor device including: a conductive support including a first die pad and a second die pad having a potential different from a potential of the first die pad; a first semiconductor element mounted on the first die pad; a second semiconductor element mounted on the second die pad; and a sealing resin that covers the first semiconductor element, the second semiconductor element, and at least a portion of the conductive support.

A capacitive digital isolator circuit includes: a signal emitting module; a signal receiving module; and a capacitive isolation module. The signal emitting module includes an edge Pulse-Coding modulator circuit, which modulates an input signal to generate a pair of differential modulated signals based on the input signal and transmits the pair of differential modulated signals to the signal receiving module. Each of the pair of differential modulated signals has twelve high-frequency pulses when the input signal has a rising edge and has six high-frequency pulses when the input signal has a falling edge. The signal receiving module includes an ultra-low power consumption high-speed comparator, a timer and a pulse counter. An output signal of the pulse counter has a rising edge when the pulse number of the comparator output signal is larger than nine and a falling edge when the pulse number is equal to or smaller than nine.

An isolator includes a first insulating portion, a first electrode provided in the first insulating portion, a second insulating portion provided on the first insulating portion and the first electrode, a third insulating portion provided on the second insulating portion, and a second electrode provided in the third insulating portion. The second insulating portion includes a plurality of first voids and a second void. The plurality of first voids are arranged in a first direction parallel to an interface between the first insulating portion and the second insulating portion. At least one of the first voids is provided under the second void.

A digital isolator provided includes a pair of transceiver circuits and a control circuit. Each transceiver circuit includes a transmitter circuit, a receiver circuit, and a DC isolation circuit. When the control circuit controls one of the pair of transceiver circuits to operate in a transmitting mode and the other of the pair of transceiver circuits to operate in a receiving mode, the transmitting circuit of the transceiver circuit operating in the transmitting mode receives a square wave signal to generate a pair of differential square wave signals, the connected DC isolation circuits receive the pair of differential square wave signals to generate a pair of differential coupling signals, and the transceiver circuit operating in the receiving mode uses the pair of differential coupling signals to output the square wave signal through the design of a pair of feedback voltage divider circuits and a differential comparison circuit included therein.

A low voltage drive circuit (LVDC) includes a digital to digital converter that converts transmit digital data into a digital input signal, wherein the transmit digital data is synchronized to a clock rate of a host device and the digital input signal is synchronized to a clock rate of a bus to which the LVDC is coupled. An output limited digital to analog is converter converts the digital input signal into analog outbound data by generating a DC component and converting the digital input signal into an oscillating component at a first frequency, wherein magnitude of the oscillating component is limited to a range that is less than a difference between magnitudes of power supply rails of the LVDS, and wherein the oscillating component and the DC component are combined to produce the analog outbound data. A drive sense circuit conveys the analog outbound data as variances in loading of the bus at the first frequency and wherein analog inbound data is represented within an analog receive signal as variances in loading of the bus at a second frequency.