Abstract: An example boosted switch driver circuit includes two branches. The first branch includes a first transistor. The second branch includes a second transistor and a level shifter circuit. One of the transistors is an N-type transistor and the other one is a P-type transistor. The circuit is configured to split an input clock signal between the first branch and the second branch, so that a portion of the input clock signal split to the first branch is provided to the first transistor, and a portion of the input clock signal split to the second branch is level-shifted by the level shifter circuit to generate a level-shifted input clock signal and the level-shifted input clock signal is provided to the second transistor. The circuit is further configured to combine an output of the first transistor and an output of the second transistor to generate an output clock signal.

Abstract: In pipelined analog-to-digital converters (ADCs), a passive switched capacitor (PSWC) circuit can be used in a multiplying analog-to-digital converter (MDAC), which generates an analog output being fed to a subsequent stage. Complementary analog input signals are sampled respectively onto first and second capacitors, which are stacked to provide gain. The first capacitor is positioned between a first input switch and an output node of the PSWC circuit, and the second capacitor is positioned between the second input switch and a digital-to-analog converter (DAC) output. The topology advantageously isolates common modes of the complementary analog input signals, the DAC output, and the output of the PSWC circuit. As a result, the topology offers more degrees of freedom in the overall circuit design when stages having the MDAC are cascaded, resulting in pipelined ADCs with a more elegant design with lower noise and lower power consumption.

Abstract: A clock shifter circuit may receive a input clock in a first voltage domain and may generate a level-shifted output clock in a second voltage domain. The circuit may include a cross-coupled pair of transistor switches and a pair of capacitors. Each switch may have a drain coupled to one of the capacitors, a source coupled to a circuit supply voltage, and a gate coupled to the other capacitor. One capacitor may receive a true input clock version, while the other may receive a complement version. Each capacitor, in an alternating manner, may activate an opposing transistor switch to charge its capacitor during an active phase of its respective input clock. The circuit may generate the output clock from an output node connected between one of the transistor switches and its capacitor. The output clock may drive a load directly coupled to the output node.

Abstract: Circuits and methods are introduced to allow for timing relationship between a clock signal and a synchronization signal to be observed. The observations may include observing the timing relationship between a capture edge of the clock signal and a transition of the synchronization signal. Based on the observations the timing of the synchronization signal transition may be adjusted. Observing the timing relationship may include providing a delayed synchronization signal and a delayed clock signal. The delayed synchronization signal may provide what happens before the capture edge of the clock signal. The delayed clock signal may provide what happens after the capture edge of the clock signal.

Abstract: One embodiment relates to an apparatus configured to cancel charge injected on a node of a differential pair of nodes. A dummy circuit element can inject charge on an inverted node to cancel charge injected on a non-inverted node by a switch when the switch is switched off. In addition, another dummy circuit element can inject charge on the non-inverted node to cancel charge injected on the inverted node by another switch when the other switch is switched off. These dummy circuits elements can be cross-coupled.

Abstract: One embodiment relates to an apparatus configured to cancel charge injected on a node of a differential pair of nodes. A dummy circuit element can inject charge on an inverted node to cancel charge injected on a non-inverted node by a switch when the switch is switched off. In addition, another dummy circuit element can inject charge on the non-inverted node to cancel charge injected on the inverted node by another switch when the other switch is switched off. These dummy circuits elements can be cross-coupled.

Abstract: A clock shifter circuit may receive a input clock in a first voltage domain and may generate a level-shifted output clock in a second voltage domain. The circuit may include a cross-coupled pair of transistor switches and a pair of capacitors. Each switch may have a drain coupled to one of the capacitors, a source coupled to a circuit supply voltage, and a gate coupled to the other capacitor. One capacitor may receive a true input clock version, while the other may receive a complement version. Each capacitor, in an alternating manner, may activate an opposing transistor switch to charge its capacitor during an active phase of its respective input clock. The circuit may generate the output clock from an output node connected between one of the transistor switches and its capacitor. The output clock may drive a load directly coupled to the output node.

Abstract: Apparatus and methods for pipelined analog-to-digital conversion are disclosed. In some embodiments, a pipeline analog-to-digital converter includes a plurality of multiplying digital-to-analog converter (MDAC) stages coupled in cascade. At least one of the MDAC stages includes two or more flash ADCs connected in parallel, operating alternately to generate digital signals from an analog input voltage. In one embodiment, the flash ADCs provide the digital signals in an alternating manner to a capacitor block that receives a delayed analog input voltage. In another embodiment, the at least one MDAC may include two or more capacitor blocks, each of which is associated with a respective one of the flash ADCs, forming two or more sets of a flash ADC and a capacitor block. In yet another embodiment, the at least one MDAC also include three or more capacitor blocks, each of which can be randomly selected for one of the flash ADCs.

Abstract: Apparatus and methods for pipelined analog-to-digital conversion are disclosed. In some embodiments, a pipelined analog-to-digital converter includes a control and correction circuit; and a plurality of MDAC stages. At least one of the MDAC stages includes: an MDAC input to receive an analog input voltage; and a dual latch flash ADC comprising one or more dual latch comparators. At least one of the dual latch comparators includes: a pre-amplifier having an input coupled to the MDAC input, and an output; a demultiplexer having an input coupled to the output of the pre-amplifier, a first output, and a second output; a first latch having an input coupled to the first output of the demultiplexer, wherein the first latch may generate a first digital signal; and a second latch having an input coupled to the second output of the demultiplexer, wherein the second latch may generate a second digital signal.

Abstract: Apparatus and methods for pipelined analog-to-digital conversion are disclosed. In some embodiments, a pipelined analog-to-digital converter includes a control and correction circuit; and a plurality of MDAC stages. At least one of the MDAC stages includes: an MDAC input to receive an analog input voltage; and a dual latch flash ADC comprising one or more dual latch comparators. At least one of the dual latch comparators includes: a pre-amplifier having an input coupled to the MDAC input, and an output; a demultiplexer having an input coupled to the output of the pre-amplifier, a first output, and a second output; a first latch having an input coupled to the first output of the demultiplexer, wherein the first latch may generate a first digital signal; and a second latch having an input coupled to the second output of the demultiplexer, wherein the second latch may generate a second digital signal.

Abstract: Apparatus and methods for pipelined analog-to-digital conversion are disclosed. In some embodiments, a pipeline analog-to-digital converter includes a plurality of multiplying digital-to-analog converter (MDAC) stages coupled in cascade. At least one of the MDAC stages includes two or more flash ADCs connected in parallel, operating alternately to generate digital signals from an analog input voltage. In one embodiment, the flash ADCs provide the digital signals in an alternating manner to a capacitor block that receives a delayed analog input voltage. In another embodiment, the at least one MDAC may include two or more capacitor blocks, each of which is associated with a respective one of the flash ADCs, forming two or more sets of a flash ADC and a capacitor block. In yet another embodiment, the at least one MDAC also include three or more capacitor blocks, each of which can be randomly selected for one of the flash ADCs.

Abstract: An improved pipelined analog to digital converter that facilitates calibration for non-linearity errors and a method for obtaining calibration values. The analog to digital converter has a calibration mode in which the output bits for stages in the pipeline can be coupled to output pins of the device. Device pins that are used in normal operating mode to output the most significant bits of the ADC output are used in calibration mode to make available output bits of a pipeline stage being calibrated. A calibration method takes advantage of the outputs of the stages being directly observable to compute calibration values. The output bits of a pipeline stage are monitored as the analog input to the ADC is increased. A change in these bits identifies a subrange boundary. Errors are measured for values immediately above and immediately below each subrange boundary and used to compute correction factors.

Abstract: Methods and apparatus for calibrating one or more signals of an electronic device are provided. Calibration coefficients are stored in a memory, such as a fuse bank, to be applied to correct the one or more signals. A selection multiplexer is provided, the selection multiplexer capable of assigning one of a number of bit weight configurations to the calibration coefficients to set a desired range and resolution for calibration information applied to the one or more signals of the electronic device.

Abstract: Spurious energy suppression for a data communication system is achieved without using a large order noise suppression filter, by means of a pre-mixer tracking filter incorporated into an emitter-coupled logic configured buffer of a carrier frequency generator, using a MOSFET-implemented current-controlled resistance component of a resistor-capacitor network and an associated current control stage. The MOSFET-implemented resistance components of the filter are controlled by the same control current that establishes the carrier generator's output frequency. As a result, the cut-off frequency of the tracking filter is linearly proportional to the carrier and effectively independent of process parameters.

Abstract: A circuit and method for adjusting a cutoff frequency of an active filter, such as a gm-C filter, which has a common mode feedback circuit for providing a bias signal may include plural common base stages having first inputs connected in parallel to a stage of the active filter and second inputs connected in parallel to an output from the common mode feedback circuit, and a capacitor connected to an output from each of the common base stages. The common base stages and their connected capacitors are selectively isolated from the filter output to adjust the cutoff frequency of the filter. The deselected common base stages are also isolated from the common mode feedback circuit and bias generator inputs.