A data pipeline circuit includes an upstream interface circuit that receives sequential data and a downstream interface circuit that transfers the sequential data to a downstream circuit. A ready signal indicates the downstream circuit is ready to receive the sequential data. The data pipeline circuit includes a first data latch, a second data latch and a first status latch. The first data latch receives the sequential data. The first status latch generates an available signal that is asserted to indicate the second data latch is available to receive the sequential data. The second data latch receives the sequential data in response on the available signal being asserted and the ready signal indicating the downstream circuit is not ready to receive the sequential data on the data output. Limiting conditions in which the sequential data is stored in the second data latch significantly reduces power consumption of the data pipeline circuit.

Composite interface circuit including bidirectional single-conductor bus, first switching circuit, and second switching circuit. Bidirectional single-conductor bus is coupled by first pull-up resistor (R1) with first direct current (“DC”) input current source having first voltage (V1). First switching circuit includes first transistor (T1) being coupled with first pull-up resistor (R1) and with bidirectional single-conductor bus. Second switching circuit includes second transistor (T2) being coupled by second pull-up resistor (R2) with second DC input current source having second voltage (V2). Second switching circuit further includes voltage divider coupling second transistor (T2) with bidirectional single-conductor bus. First and second switching circuits are respectfully configured for being coupled with first transmitter conductor (Tx1) and first receiver conductor (Rx1) of full duplex universal asynchronous data communication interface.

A method for a low voltage drive circuit (LVDC) begins by receiving data from one or more other low voltage drive circuits (LVDCs) using a bus with varying loading at one or more frequencies and continues by sampling one or more data values of the data to produce a sampled digital data value, converting the sampled digital data value to a binary string and writing the binary string to a buffer. The method continues by writing one or more additional binary strings to the buffer to form a digital word, outputting the digital word to a digital converter circuit and formatting the digital word to create a formatted digital word. The method continues by writing the formatted digital word to a second buffer, writing additional formatted digital words to the second buffer to form a data packet and finally, outputting the data packet to a host device.

Embodiments of the present disclosure relate to the field of battery technologies, and disclose a pre-charging circuit for a high voltage battery pack and a pre-charging method therefor. In some embodiments of the present disclosure, during a charging process, a control module switches on a charging switching module and switches off a charging pre-charging module after determining that a voltage at the first end of the charging switching module and a voltage at the second end of the charging switching module comply with a first constraint relationship; during a discharging process, the control module switches on the main positive switching module and switches off the main positive pre-charging module after determining that a voltage at the first end of the main positive switching module and a voltage at the second end of the main positive switching module comply with a second constraint relationship.

Charge transfer between gate terminals of sub-threshold current reduction circuit (SCRC) transistors and related apparatuses and methods are disclosed. An apparatus includes a first output terminal electrically connected to a pull-up gate terminal of at least one pull-up SCRC transistor and a second output terminal electrically connected to a pull-down gate terminal of at least one pull-down SCRC transistor. The apparatus also includes a first resistive path between a first input terminal and the first output terminal and a second resistive path between the second input terminal and the second output terminal. The apparatus further includes a charge transfer gate electrically connected between the first resistive path and the second resistive path.

Charge transfer between gate terminals of sub-threshold current reduction circuit (SCRC) transistors and related apparatuses and methods is disclosed. An apparatus includes a pull-up SCRC transistor, a pull-down SCRC transistor, and a charge transfer circuit. The pull-up SCRC transistor includes a pull-up gate terminal. The pull-down SCRC transistor includes a pull-down gate terminal. The charge transfer circuit is electrically connected between the pull-up gate terminal and the pull-down gate terminal. The charge transfer circuit is configured to transfer charge between the pull-up gate terminal and the pull-down gate terminal.

The present invention provides a memory controller including a plurality of channels. A first channel of the plurality of channels includes a first transmitter, a first pull-up variable resistor and a first pull-down variable resistor, wherein the first transmitter is configured to generate a first data signal to a memory module, the first pull-up variable resistor is coupled between a supply voltage and an output terminal of the first transmitter, and the first pull-down variable resistor is coupled to the output terminal of the first transmitter. The control circuit is coupled to the plurality of channels, and is configured to control the first pull-up variable resistor and/or the first pull-down variable resistor according to a reference voltage used by the memory module.

Composite interface circuit including bidirectional single-conductor bus, first switching circuit, and second switching circuit. Bidirectional single-conductor bus is coupled by first pull-up resistor (R1) with first direct current (“DC”) input current source having first voltage (V1). First switching circuit includes first transistor (T1) being coupled with first pull-up resistor (R1) and with bidirectional single-conductor bus. Second switching circuit includes second transistor (T2) being coupled by second pull-up resistor (R2) with second DC input current source having second voltage (V2). Second switching circuit further includes voltage divider coupling second transistor (T2) with bidirectional single-conductor bus. First and second switching circuits are respectfully configured for being coupled with first transmitter conductor (Tx1) and first receiver conductor (Rx1) of full duplex universal asynchronous data communication interface.

A hardware device, inserted in a universal serial bus port of a computing device, is detected. A counter is set to an initial value of one. In response to determining that one or more device descriptors associated with the hardware device are not received by the computing device within a predetermined time period, the hardware device is prevented from discharging a high-voltage charge into the computing device by inhibiting the hardware device from storing the high-voltage charge in a capacitor of the hardware device.

Disclosed is a home bus system (HBS) circuit, applicable to home bus (HB) communication implemented using a Microchip chip. The circuit includes the Microchip chip, an HBS communication chip, a resistor, a capacitor, and a triode, the Microchip chip includes a universal asynchronous receiver/transmitter (UART) input pin and a serial peripheral interface (SPI) output pin, and the HBS communication chip includes an input pin. The triode has a base coupled to the SPI output pin and a first end of the capacitor, a collector coupled to a first end of the resistor and the input pin of the HBS communication chip, and an emitter grounded, wherein a second end of the resistor is coupled to a power supply, and a second end of the capacitor is grounded.