Abstract: A non-linearity correction module, an optional droop corrector, and a zero-IF receiver with the non-linearity correction module and an optional droop corrector, wherein the non-linearity correction module is configured to generate a non-linearity term scaled to mitigate an inter-modulation component term of a RF signal received by the zero-IF receiver based on a test signal to enhance linearity in the zero-IF receiver and the optional droop corrector is configured to compensate a droop within a signal band of interest, caused by an analog low pass filter filtering a RF signal received by the zero-IF receiver, before a down-converted RF signal is fed into the non-linearity module.

Abstract: Techniques maintaining receiver reliability, including determining a present attenuation level for an attenuator, wherein the attenuation level is set by a gain controller, determining a relative reliability threshold based on the present attenuation level, receiving a radio frequency (RF) signal, determining a voltage level of the received RF signal, comparing the voltage level of the received RF signal to the relative reliability threshold to determine that a reliability condition exists, and overriding, in response to the determination that the reliability condition exists, the present attenuation level set by the gain controller with an override attenuation level based on the present attenuation level.

Abstract: A system includes a Zero IF transmitter having a mixer and a programmable gain stage. The Zero IF transmitter also includes an intermediate stage between the mixer and the programmable gain stage, wherein the intermediate stage is configured to decouple the mixer and the programmable gain stage.

Abstract: A circuit includes a filter, a first inverter, and a second inverter. The filter is coupled to an input of the first inverter. The second inverter includes an input and an output. The input of the second inverter is coupled to the output of the first inverter. The output of the second inverter is coupled to the input of the first inverter.

Abstract: A system includes a Zero IF transmitter having a mixer and a programmable gain stage. The Zero IF transmitter also includes an intermediate stage between the mixer and the programmable gain stage, wherein the intermediate stage is configured to decouple the mixer and the programmable gain stage.

Abstract: A spur cancellation circuit for use in a mixed signal circuit. A spur cancellation circuit includes a clock generation circuit, a flip-flop bank, and a control circuit. The clock generation circuit is configured to generate a clock signal. The flip-flop bank is coupled to the clock generation circuit, and includes a plurality of flip-flops configured to be clocked by the clock signal. The control circuit is coupled to the clock generation circuit and the flip-flop bank. The control circuit is configured to individually enable one or more of the flip-flops to change state responsive to the clock signal and consume a predetermined amount of power; and to provide a data value to be clocked into the flip-flops.

Abstract: A system includes a Zero IF transmitter having a mixer and a programmable gain stage. The Zero IF transmitter also includes an intermediate stage between the mixer and the programmable gain stage, wherein the intermediate stage is configured to decouple the mixer and the programmable gain stage.

Abstract: A spur cancellation circuit for use in a mixed signal circuit. A spur cancellation circuit includes a clock generation circuit, a flip-flop bank, and a control circuit. The clock generation circuit is configured to generate a clock signal. The flip-flop bank is coupled to the clock generation circuit, and includes a plurality of flip-flops configured to be clocked by the clock signal. The control circuit is coupled to the clock generation circuit and the flip-flop bank. The control circuit is configured to individually enable one or more of the flip-flops to change state responsive to the clock signal and consume a predetermined amount of power; and to provide a data value to be clocked into the flip-flops.

Abstract: A non-linearity correction module, an optional droop corrector, and a zero-IF receiver with the non-linearity correction module and an optional droop corrector, wherein the non-linearity correction module is configured to generate a non-linearity term scaled to mitigate an inter-modulation component term of a RF signal received by the zero-IF receiver based on a test signal to enhance linearity in the zero-IF receiver and the optional droop corrector is configured to compensate a droop within a signal band of interest, caused by an analog low pass filter filtering a RF signal received by the zero-IF receiver, before a down-converted RF signal is fed into the non-linearity module.

Abstract: A modulator of an analog to digital converter includes a quantizer component configured to generate a digital signal based on a clock input operating at a sample rate. The modulator further includes a first digital to analog converter (DAC) configured to generate first DAC output at half the sample rate. The modulator further includes a second DAC configured to generate second DAC output at half the sample rate, where the first DAC and the second DAC are updated at alternate cycles of the clock input.

Abstract: A modulator of an analog to digital converter includes a quantizer component configured to generate a digital signal based on a clock input operating at a sample rate. The modulator further includes a first digital to analog converter (DAC) configured to generate first DAC output at half the sample rate. The modulator further includes a second DAC configured to generate second DAC output at half the sample rate, where the first DAC and the second DAC are updated at alternate cycles of the clock input.

Abstract: A circuit includes first and second operational amplifiers, each including positive and negative inputs and first and second internal nodes. A mixer couples first and second input nodes to the positive and negative inputs of the operational amplifiers. The mixer switches the first and second input nodes between the positive and negative inputs of the first and second operational amplifiers in accordance with clock signals. A first cancellation capacitor couples to the first input node, and a second cancellation capacitor couple to the second input node. First and second switches selectively couple the first cancellation capacitor to the first and second internal nodes, respectively, of the first operational amplifier. Third and fourth switches selectively couple the second cancellation capacitor to the first and second internal nodes, respectively, of the second operational amplifier.

Abstract: At least some embodiments are directed to a system that comprises a differential switch network comprising first and second output nodes, first and second transistors coupled to the network, and first and second resistors coupled to the first and second transistors. The DAC also comprises a voltage source coupled to the first resistor and a ground connection coupled to the second resistor. The DAC further includes a capacitor coupled to the first and second transistors and to the second resistor.

Abstract: A comparator includes a differential input pair of transistors, a pair of cross coupled n-channel metal-oxide-semiconductor field-effect (NMOS) transistors, a pair of p-channel metal-oxide semiconductor field-effect (PMOS) transistors, a first inverter, and a second inverter. The differential input pair of transistors includes a first input transistor and a second input transistor. The pair of cross coupled NMOS transistors includes a first NMOS transistor and a second NMOS transistor. The pair of PMOS transistors includes a first PMOS transistor and a second PMOS transistor. The pair of PMOS transistors are coupled to the pair of cross coupled NMOS transistors. The first inverter is coupled in series with the first PMOS transistor. The second inverter is coupled in series with the second PMOS transistor.

Abstract: At least some embodiments are directed to a system that comprises a differential switch network comprising first and second output nodes, first and second transistors coupled to the network, and first and second resistors coupled to the first and second transistors. The DAC also comprises a voltage source coupled to the first resistor and a ground connection coupled to the second resistor. The DAC further includes a capacitor coupled to the first and second transistors and to the second resistor.

Abstract: A direct conversion radio frequency receiver comprising: a clock generator to provide a first clock signal and a second clock signal; a first node; a second node; a zero-intermediate frequency (zero-IF) mixer coupled to the first and second nodes, clocked by the first and second clock signals, and comprising a first transimpedance amplifier and a second transimpedance amplifier to provide a direct-conversion voltage; a current injector, coupled to the first and second nodes, configurable to inject into the first and second nodes a common mode current or a differential mode current; and a controller, coupled to the zero-IF mixer and the current injector, to adjust at least one of the first and second transimpedance amplifiers based on the direct-conversion voltage when the current injector is to inject the common mode current.

Abstract: A voltage regulator that provides feedforward cancellation of power supply noise is disclosed. The voltage regulator includes a process tracking circuit that receives a supply voltage and generates a proportional voltage. A tracking capacitor is coupled to the process tracking circuit and generates an injection voltage based on the proportional voltage. An Ahuja compensated regulator generates a regulated voltage. The injection voltage is provided on a feedback path of the Ahuja compensated regulator.

Abstract: At least some embodiments are directed to a system that comprises a differential switch network comprising first and second output nodes, first and second transistors coupled to the network, and first and second resistors coupled to the first and second transistors. The DAC also comprises a voltage source coupled to the first resistor and a ground connection coupled to the second resistor. The DAC further includes a capacitor coupled to the first and second transistors and to the second resistor.

Abstract: At least some embodiments are directed to a system that comprises a differential switch network comprising first and second output nodes, first and second transistors coupled to the network, and first and second resistors coupled to the first and second transistors. The DAC also comprises a voltage source coupled to the first resistor and a ground connection coupled to the second resistor. The DAC further includes a capacitor coupled to the first and second transistors and to the second resistor.

Abstract: At least some embodiments are directed to a system that comprises a differential switch network comprising first and second output nodes, first and second transistors coupled to the network, and first and second resistors coupled to the first and second transistors. The DAC also comprises a voltage source coupled to the first resistor and a ground connection coupled to the second resistor. The DAC further includes a capacitor coupled to the first and second transistors and to the second resistor.