Abstract: The present invention relates to semiconductor integrated circuitry, and in particular to such circuitry where one or a plurality of similar or identical operating units are each operable to carry out an operation dependent on a reference signal. One example of such an operating unit is a sub-ADC unit of analogue-to-digital converter (ADC) circuitry, which employs one or more such sub-ADC units to convert samples of an input analogue signal into representation digital values. Where there are a plurality of sub-ADC units, they may each convert samples of an input analogue signal into representative digital values. They may also operate in a time-interleaved manner so that their conversion rate (from sample to digital value) can be lower than the overall sample rate by a factor of the number of sub-ADC units.

Abstract: Clock distribution circuitry configured for duty cycle control, the circuitry comprising: a plurality of buffers connected in series along a clock path, each of the buffers having an input terminal and an output terminal, the input terminal being connected to the clock path via a corresponding AC coupling capacitor, and the clock, path configured to receive an input clock signal at its input node and output an output clock signal at its output node, the output clock signal having an output duty cycle; and control circuitry connected to apply a DC bias signal to the input terminal of each of the plurality of buffers, wherein the control circuitry is configured to: obtain a measurement signal indicative of the output duty cycle; and control the DC bias signals, based on a difference between the measurement signal and a reference signal, so as to control the output duty cycle.

Abstract: The present invention relates to semiconductor integrated circuitry, and in particular to such circuitry where one or a plurality of similar or identical operating units are each operable to carry out an operation dependent on a reference signal. One example of such an operating unit is a sub-ADC unit of analogue-to-digital converter (ADC) circuitry, which employs one or more such sub-ADC units to convert samples of an input analogue signal into representation digital values. Where there are a plurality of sub-ADC units, they may each convert samples of an input analogue signal into representative digital values. They may also operate in a time-interleaved manner so that their conversion rate (from sample to digital value) can be lower than the overall sample rate by a factor of the number of sub-ADC units.

Abstract: Clock distribution circuitry configured for duty cycle control, the circuitry comprising: a plurality of buffers connected in series along a clock path, each of the buffers having an input terminal and an output terminal, the input terminal being connected to the clock path via a corresponding AC coupling capacitor, and the clock, path configured to receive an input clock signal at its input node and output an output clock signal at its output node, the output clock signal having an output duty cycle; and control circuitry connected to apply a DC bias signal to the input terminal of each of the plurality of buffers, wherein the control circuitry is configured to: obtain a measurement signal indicative of the output duty cycle; and control the DC bias signals, based on a difference between the measurement signal and a reference signal, so as to control the output duty cycle.

Abstract: There is disclosed herein integrated circuitry comprising a clock path for carrying a clock signal from a clock source to a circuit block, the circuit block being operable based on the clock signal. Clock buffer circuitry is provided along the clock path for buffering the clock signal. A tuneable inductance is connected to the clock path. A capacitor is connected to the clock path so as to form an AC coupling capacitor connected in series along the path, and is implemented between metal layers of the integrated circuitry.

Abstract: There is disclosed herein multiplexer circuitry. In particular, there is disclosed a latch circuit for use as a multiplexer to multiplex information carried by respective pairs of input information signals onto an output information signal, each pair of input information signals comprising a first input information signal and a second input information signal, and each pair of input information signals carrying information values based on signal values of those input information signals and interleaved with information values carried by the other pair or pairs of input information signals.

Abstract: There is disclosed herein a circuitry system comprising first and second IC chips, configured or configurable such that; the first IC chip has an output terminal connected to receive an output signal from an output-signal unit of the first IC chip, the output-signal unit being connected between high and low voltage-reference sources of the first IC chip, the high and low voltage-reference sources being connected to respective high and low voltage-reference terminals of the first IC chip; and the second IC chip has an input terminal connected in a potential-divider arrangement between high and low voltage-reference terminals of the second IC chip, wherein: the high and low voltage-reference terminals of the first IC chip are respectively connected to the high and low voltage-reference terminals of the second IC chip; and the output terminal of the first IC chip is connected to the input terminal of the second IC chip.

Abstract: There is disclosed herein current-mode circuitry for measuring a timing difference between first and second signals, the circuitry comprising: a tail node configured during a measurement operation to receive a current pulse in dependence upon the first signal; first and second nodes conductively connectable to said tail node along respective first and second paths; and steering circuitry configured during the measurement operation to control such connections between the tail node and the first and second nodes based on the second signal to steer the current pulse so that a first portion of the current pulse passes along the first path and a second portion of the current pulse passes along the second path in dependence upon the timing difference between said first and second signals; and a signal output unit configured to output a measurement-result signal indicating a measure of said timing difference based upon one or both of the first and second portions.

Abstract: Switching circuitry for use in a digital-to-analog converter, the circuitry comprising: a common node; first and second output nodes; and a plurality of switches connected between the common node and the first and second output nodes and operable in each clock cycle of a series of clock cycles, based on input data, to conductively connect the common node to either the first or second output node along a given one of a plurality of paths, wherein the circuitry is arranged such that a data-controlled switch and a clock-controlled switch are provided in series along each said path from the common node to the first or second output node.

Abstract: There is disclosed herein integrated circuitry, comprising a signal path connected to a connection pad, for connection to external circuitry; and a termination circuit connected between the signal path and a voltage reference, wherein the termination circuit comprises a resistor and an inductor. The resistor and the inductor are connected together so as to compensate for parasitic capacitance associated with the connection pad. The signal path may carry an output signal from high-speed circuitry such as digital-to-analog converter circuitry.

Abstract: There is disclosed herein analogue-to-digital converter circuitry, comprising a set of sub-ADC units each for carrying out analogue-to-digital conversion operations, the set comprising a given number of core sub-ADC units for carrying out said given number of core conversion operations. Also provided is control circuitry operable, when a said sub-ADC unit is determined to be a defective sub-ADC unit, to cause the core conversion operations to be carried by the sub-ADC units of the set sub-ADC units other than the defective sub-ADC unit.

Abstract: There is disclosed herein clock generation circuitry, in particular rotary travelling wave oscillator circuitry. Such circuitry comprises a pair of signal lines connected together to form a closed loop and arranged such that they define at least one transition section where both said lines in a first portion of the pair cross from one lateral side of both said lines in a second portion of the pair to the other lateral side of both said lines in the second portion of the pair.

Abstract: There is disclosed herein charge-mode circuitry for use in a comparator to capture a difference between magnitudes of first and second input signals, the circuitry comprising: a tail node configured during a capture operation to receive a charge packet; first and second nodes conductively connectable to said tail node along respective first and second paths; and control circuitry configured during the capture operation to control such connections between the tail node and the first and second nodes based on the first and second input signals such that said charge packet is divided between said first and second paths in dependence upon the difference between magnitudes of the first and second input signals.

Abstract: There is disclosed herein analogue-to-digital converter circuitry, comprising a set of sub-ADC units each for carrying out analogue-to-digital conversion operations, the set comprising a given number of core sub-ADC units for carrying out said given number of core conversion operations. Also provided is control circuitry operable, when a said sub-ADC unit is determined to be a defective sub-ADC unit, to cause the core conversion operations to be carried by the sub-ADC units of the set sub-ADC units other than the defective sub-ADC unit.

Abstract: There is disclosed herein integrated circuitry,comprising a signal path connected to a connection pad, for connection to external circuitry; and a termination circuit connected between the signal path and a voltage reference, wherein the termination circuit comprises a resistor and an inductor. The resistor and the inductor are connected together so as to compensate for parasitic capacitance associated with the connection pad. The signal path may carry an output signal from high-speed circuitry such as digital-to-analogue converter circuitry.

Abstract: There is disclosed herein current-mode circuitry for measuring a timing difference between first and second signals, the circuitry comprising: a tail node configured during a measurement operation to receive a current pulse in dependence upon the first signal; first and second nodes conductively connectable to said tail node along respective first and second paths; and steering circuitry configured during the measurement operation to control such connections between the tail node and the first and second nodes based on the second signal to steer the current pulse so that a first portion of the current pulse passes along the first path and a second portion of the current pulse passes along the second path in dependence upon the timing difference between said first and second signals; and a signal output unit configured to output a measurement-result signal indicating a measure of said timing difference based upon one or both of the first and second portions.

Abstract: There is disclosed herein clock generation circuitry, in particular rotary travelling wave oscillator circuitry. Such circuitry comprises a pair of signal lines connected together to form a dosed loop and arranged such that they define at least one transition section where both said lines in a first portion of the pair cross from one lateral side of both said lines in a second portion of the pair to the other lateral side of both said lines in the second portion of the pair.

Abstract: There is disclosed herein integrated circuitry comprising a clock path for carrying a clock signal from a clock source to a circuit block, the circuit block being operable based on the clock signal. Clock buffer circuitry is provided along the clock path for buffering the clock signal. A tuneable inductance is connected to the clock path. A capacitor is connected to the clock path so as to form an AC coupling capacitor connected in series along the path, and is implemented between metal layers of the integrated circuitry.

Abstract: There is disclosed herein a circuitry system comprising first and second IC chips, configured or configurable such that; the first IC chip has an output terminal connected to receive an output signal from an output-signal unit of the first IC chip, the output-signal unit being connected between high and low voltage-reference sources of the first IC chip, the high and low voltage-reference sources being connected to respective high and low voltage-reference terminals of the first IC chip; and the second IC chip has an input terminal connected in a potential-divider arrangement between high and low voltage-reference terminals of the second IC chip, wherein: the high and low voltage-reference terminals of the first IC chip are respectively connected to the high and low voltage-reference terminals of the second IC chip; and the output terminal of the first IC chip is connected to the input terminal of the second IC chip.

Abstract: There is disclosed herein multiplexer circuitry. In particular, there is disclosed a latch circuit for use as a multiplexer to multiplex information carried by respective pairs of input information signals onto an output information signal, each pair of input information signals comprising a first input information signal and a second input information signal, and each pair of input information signals carrying information values based on signal values of those input information signals and interleaved with information values carried by the other pair or pairs of input information signals.