System and method for correcting integral nonlinearity in an oscillator system
First Claim
1. A wireless communication element, comprising:
- a receive path configured to receive a first wireless communication signal and convert the first wireless communication signal into a first digital signal based at least on an oscillator signal;
a transmit path configured to convert a second digital signal into a second wireless communication signal based at least on the oscillator signal and transmit the second wireless communication signal;
an oscillator configured to output the oscillator signal to at least one of the receive path and the transmit path, the oscillator configured to operate at an operating frequency based on an applied frequency control signal; and
a frequency control path configured to generate the applied frequency control signal, the frequency control path comprising;
an integral non-linearity compensation module configured to generate a compensated frequency control signal value based on a received frequency control signal value received by the integral non-linearity compensation module and an integral non-linearity compensation value associated with the received frequency control signal value; and
a digital-to-analog converter configured to generate the applied frequency control signal based on the compensated frequency control signal value generated by the integral non-linearity compensation module.
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Accused Products
Abstract
A method may include measuring a frequency difference between an actual frequency and an expected frequency associated with a frequency control calibration signal value for each of a plurality of frequency control calibration signal values during a calibration phase. The method may additionally include generating integral non-linearity compensation values based on the frequency differences measured. The method may further include generating the applied frequency control signal based on a frequency control calibration signal value received by the digital-to-analog converter during the calibration phase. The method may also include generating a compensated frequency control signal value based on a frequency control signal value received by the integral non-linearity compensation module and an integral non-linearity compensation value associated with the frequency control signal value during an operation phase of the wireless communication element.
16 Citations
10 Claims
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1. A wireless communication element, comprising:
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a receive path configured to receive a first wireless communication signal and convert the first wireless communication signal into a first digital signal based at least on an oscillator signal; a transmit path configured to convert a second digital signal into a second wireless communication signal based at least on the oscillator signal and transmit the second wireless communication signal; an oscillator configured to output the oscillator signal to at least one of the receive path and the transmit path, the oscillator configured to operate at an operating frequency based on an applied frequency control signal; and a frequency control path configured to generate the applied frequency control signal, the frequency control path comprising; an integral non-linearity compensation module configured to generate a compensated frequency control signal value based on a received frequency control signal value received by the integral non-linearity compensation module and an integral non-linearity compensation value associated with the received frequency control signal value; and a digital-to-analog converter configured to generate the applied frequency control signal based on the compensated frequency control signal value generated by the integral non-linearity compensation module. - View Dependent Claims (2, 3, 4, 5)
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6. A method comprising:
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receiving a first wireless communication signal and converting the first wireless communication signal into a first digital signal based at least on an oscillator signal; converting a second digital signal into a second wireless communication signal based at least on the oscillator signal and transmitting the second wireless communication signal; providing the oscillator signal to at least one of the receive path and the transmit path, the oscillator signal having a frequency based on an applied frequency control signal; generating a compensated frequency control signal value based on a frequency control signal value received by the integral non-linearity compensation module and an integral non-linearity compensation value associated with the frequency control signal value during an operation phase of the wireless communication element; and generating the applied frequency control signal based on the compensated frequency control signal value generated by the integral non-linearity compensation module during the operation phase. - View Dependent Claims (7, 8, 9, 10)
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Specification