A termination for a high-frequency transmission line includes a first resistor that has a first terminal coupled to a first end of a transmission line and a second terminal coupled to a first input/output pad, and a second resistor that has a first terminal coupled to the first input/output pad. The first resistor and the second resistor may provide a combined resistance that matches a nominal value of a characteristic impedance of the transmission line. The apparatus may include a third resistor having a first terminal coupled to a second end of a transmission line, and a second terminal coupled to a second input/output pad, and a fourth resistor having a first terminal coupled to the second input/output pad. The third resistor and the fourth resistor may provide a combined resistance that matches the nominal value of the characteristic impedance of the transmission line.

The present invention addresses the problem of many man-hours being required for a hardware engineer to adjust a resistance value such that the rise time of a signal input to an LSI body falls within a defined range. To solve this problem, the present invention provides a control circuit provided with: a conductive wire for transmitting an input electric signal to an integrated circuit; a resistance circuit which has a variable resistance value and which is connected to the conductive wire and grounded; a measurement means for measuring a rise time of the electric signal transmitted through the conductive wire, that is, the amount of time it takes for the voltage value of the electric signal to reach a predetermined second voltage value from a predetermined first voltage value, said predetermined second voltage value being higher than the first voltage value; and a control means for changing the resistance value of the resistance circuit to a value which is lower by a specific amount when the time measured by the measurement means is shorter than the minimum time of a predetermined time range, and changing the resistance value to a value which is higher by a specific amount when the time measured by the measurement means is longer than the maximum time of the predetermined time range. The control means outputs a predetermined signal upon having changed the resistance value a predetermined number of times.

A circuit is provided for ringing suppression. The circuit comprises a termination resistor coupled to a bus via a switch; and a control circuit. The control circuit comprises an input coupled to a data input pin of a bus transceiver and an output coupled to control the termination resistor. The circuit is configured to selectively couple the resistor to the bus in response to a transition on the input bit stream.

A method of operating a storage device including first and second memory devices and a memory controller, which are connected to a single channel, the method including: transmitting first data output from the first memory device to the memory controller through a data signal line in the single channel; and transmitting a command to the second memory device through the data signal line while the memory controller receives the first data, wherein a voltage level of the data signal line is based on the command and the first data of the first memory device is loaded on the data signal line, and the first data and the command are transmitted in both directions of the data signal line.

A Controller Area Network, CAN, transceiver comprising: two terminals for coupling to a CAN bus; a transmitter arrangement configured to transmit signalling on the bus based on transmit data, the transmitter arrangement configured to drive the bus to a dominant state or recessive state based on the transmit signal; an impedance control device; a signalling detector to determine the length of time the transmit data comprises a logic zero prior to a transition to a logic one state and: based on the length of time being longer than a predetermined threshold, provide for control of an output impedance by the impedance control device in accordance with a first scheme; and based on the length of time being shorter than said predetermined threshold, provide for one of: control of said output impedance in accordance with a second scheme; and no control of the output impedance by the impedance control device.

A receiver includes a first T-coil circuit at an input of the receiver and configured to receive an input signal, a termination impedance coupled to the first T-coil circuit and configured to match an impedance of a transmission line coupled to the first T-coil circuit, and an amplifier including a first input and a second input and configured to amplify a differential signal at the first and second inputs, a calibration switch coupled to the amplifier and configured to selectively electrically connect or disconnect the first and second inputs of the amplifier, and a first receive switch configured to selectively electrically connect or disconnect a center node of the first T-coil circuit and the amplifier.

A communication method is applicable to a processing apparatus that includes a processor and a communications interface. The processor determines a first parameter corresponding to the communications interface, wherein the communications interface is connected to at least one storage apparatus and communicates with the at least one storage apparatus based on the first parameter. In this way, the processor determines a parameter used to improve a quality of signal transmission and integrity during communication between the processing apparatus and the at least one storage apparatus.

Various examples are directed to a rotary coupler and methods of use thereof. The rotary data coupler may comprise a transmitter and receiver. The transmitter may comprise a first band and a second transmitter band. The receiver may comprise a receiver housing positioned to rotate relative to the first transmitter band and the second transmitter band. A first receiver band may be positioned opposite the first transmitter band to form a first capacitor and a second receiver band may be positioned opposite the second transmitter band to form a second capacitor. The receiver may also comprise a resistance electrically coupled between the first receiver band and the second receiver band and a differential amplifier. The differential amplifier may comprise an inverting input and a non-inverting input, with the non-inverting input electrically coupled to the first receiver band and the inverting input electrically coupled to the second receiver band.

A low current line termination circuit includes first and second input interfaces each configured to receive a Vreceive+ and a Vreceive− voltage, respectively. The circuit further includes a first diode connected transistor (“DCT”) coupled to the second input interface, a first switching transistor (“ST”) coupled to the first DCT and to the first input interface, and a first delay element coupled between one of the input interfaces and a gate of the first ST. The circuit further includes a second DCT coupled to the one of the two input interfaces, a second ST coupled to the second DCT and to the second input interface, and a second delay element coupled between another of the two input interfaces and a gate of the second ST.

A Controller Area Network, CAN, transceiver comprising: two terminals for coupling to a CAN bus; a transmitter arrangement configured to transmit signalling on the bus based on transmit data, the transmitter arrangement configured to drive the bus to a dominant state or recessive state based on the transmit signal; an impedance control device; a signalling detector to determine the length of time the transmit data comprises a logic zero prior to a transition to a logic one state and: based on the length of time being longer than a predetermined threshold, provide for control of an output impedance by the impedance control device in accordance with a first scheme; and based on the length of time being shorter than said predetermined threshold, provide for one of: control of said output impedance in accordance with a second scheme; and no control of the output impedance by the impedance control device.