A level shifter with high reliability is shown, which has a cross-coupled pair and a pull-down pair. The cross-coupled pair couples a first power terminal to a first output terminal of the level shifter or a second output terminal of the level shifter. The pull-down pair has a first transistor and a second transistor, which are controlled according to an input signal of the level shifter. The first transistor is coupled between the second output terminal and a second power terminal, and the second transistor is coupled between the first output terminal and the second power terminal. A first voltage level coupled to the first power terminal is greater than a second voltage level coupled to the second power terminal, and the second voltage level is greater than the ground level.

Disclosed is a transmitter which includes a channel driver that includes a pull-up transistor and a pull-down transistor connected between a power node and a ground node and outputs a voltage between the pull-up transistor and the pull-down transistor as a transmit signal, and a pre-driver that controls the pull-up transistor and the pull-down transistor in response to a driving signal and controls the channel driver such that the transmit signal is overshot at a rising edge of the driving signal and the transmit signal is undershot at a falling edge of the driving signal.

A circuit includes an output node and an amplifier and first and second branches coupled between power supply and reference nodes. The first branch includes a first switching device coupled between a first amplifier input and the reference node, the second branch includes a second switching device coupled between the output node and a second amplifier input, and a third switching device is coupled between the power supply and output nodes. Responsive to a first voltage level on the power supply node, each of the first and second switching devices is switched off and the third switching device is switched on, and responsive to a second voltage level on the power supply node greater than the first voltage level, each of the first and second switching devices is switched on and the third switching device is switched off.

An integrated circuit comprises a power input, digital logic circuitry, a plurality of charge stores, and obscuring circuitry. The charge stores are configured to receive power from the power input, are distributed through the digital logic circuitry and are capable of providing power to the digital logic circuitry. The obscuring circuitry is configured to obscure electromagnetic emissions associated with flow of current in current loops between the plurality of charge stores and the digital logic circuitry by switching between a plurality of different charge store activation patterns, wherein each charge store activation pattern describes a different selection of one or more of the plurality of charge stores providing power to the digital logic circuitry at a given time.

A capacitive transmitter includes a control circuit configured to generate a data signal by delaying input data and to generate a control signal according to the input data and a delayed signal thereof; a capacitor connected between a first node and a transmission node; a driving circuit configured to receive the data signal and to provide an output signal corresponding to the data signal to the first node; and a bias setting circuit configured to set a transmission voltage at the transmission node according to the control signal.

An output circuit includes: a first input transistor that is provided between a first power supply line and a first intermediate node; a second input transistor that is provided between a second intermediate node and a second power supply line; a first cascode transistor that is provided between the first intermediate node and an output node, and receives a first clip voltage from a first voltage generation circuit; a second cascode transistor that is provided between the output node and the second intermediate node, and receives a second clip voltage from a second voltage generation circuit; a first switch transistor that is provided between the first intermediate node and a gate of the first cascode transistor, and turns on during power down; and a second switch transistor that is provided between the second intermediate node and a gate of the second cascode transistor, and turns on during power down.

An output circuit includes: a first input transistor that is provided between a first power supply line and a first intermediate node; a second input transistor that is provided between a second intermediate node and a second power supply line; a first cascode transistor that is provided between the first intermediate node and an output node, and receives a first clip voltage from a first voltage generation circuit; a second cascode transistor that is provided between the output node and the second intermediate node, and receives a second clip voltage from a second voltage generation circuit; a first switch transistor that is provided between the first intermediate node and a gate of the first cascode transistor, and turns on during power down; and a second switch transistor that is provided between the second intermediate node and a gate of the second cascode transistor, and turns on during power down.

The present invention discloses a switched capacitor amplifying apparatus having gain adjustment mechanism. An amplifier includes an input terminal and an output terminal. A capacitor circuit includes a sampling capacitor circuit, a load capacitor and a level-shifting capacitor array. The sampling capacitor circuit includes two sampling input terminals and a sampling output terminal to receive an input signal from a signal input terminal and output a sampled result to the input terminal of the amplifier. The load capacitor and the level-shifting capacitor array are charged according to the output terminal of the amplifier and the load capacitor is subsequently charged by the level-shifting capacitor array to accomplish level-shifting such that the load capacitor generates an output signal through a signal output terminal. A control circuit determines an enabling combination of level-shifting capacitors included in the level-shifting capacitor array to determine an equivalent capacitance, to further determine a loop gain.

The present disclosure discloses a switched capacitor amplifier apparatus for improving level-shifting. An amplifier includes input terminals and output terminals. Two capacitor circuits correspond to signal input terminals and signal output terminals and each includes a sampling capacitor circuit, a load capacitor and a level-shifting capacitor. The sampling capacitor circuit samples an input signal from one of the signal input terminals to one of the input terminals. An electrical charge neutralizing capacitor is coupled between the output terminals. The load capacitor and the level-shifting capacitor are charged according to an output from one of the output terminals in an estimation period. The level-shifting capacitor charges the load capacitor in a level-shifting period to generate an output signal at one of the signal output terminals. The electrical charge neutralizing capacitor receives and provides electrical charges from the output terminals to the level-shifting capacitor respectively in the estimation period and the level-shifting period.

A system has an unmatched communication architecture for a unidirectional command bus and compensates for drift on the command bus based on data provided on a bidirectional data bus. The memory device has an oscillator to measure drift or an amount of delay for the command bus over a time interval. The memory device can return a value over the data bus to the memory controller based on the delay measured with the oscillator. Based on receiving the value, the memory controller can adjust configuration settings for communication on the command bus.