Temperature-corrected frequency control with crystal oscillators for initial frequency acquisition
First Claim
1. A wireless communication terminal, comprising:
- a crystal oscillator, which belongs to a specified type of crystal oscillators in which a dependence of an output frequency as a function of temperature has one or more temperature dependence coefficients that vary among the crystal oscillators belonging to the specified type;
a transceiver, which is arranged to operate an Automatic Frequency Control (AFC) loop having a frequency accuracy requirement for initial AFC synchronization that is more stringent than an uncompensated frequency accuracy of the given crystal oscillator; and
circuitry, which is arranged to determine one or more output frequencies of the crystal oscillator at one or more respective operating temperatures, to compute the one or more temperature dependence coefficients for the crystal oscillator based on both of the one or more determined output frequencies and the one or more operating temperatures, to correct a frequency error in the output frequency of the crystal oscillator using the dependence and the computed temperature dependence coefficients in an initial AFC synchronization stage in which the AFC loop is unlocked, to ascertain, before receiving a signal to be tracked by the AFC loop, that the corrected frequency error meets the frequency accuracy requirement of the AFC loop, and, in a subsequent tracking stage, to lock the AFC loop on the received signal and to correct a frequency of the received signal using the locked AFC loop.
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Accused Products
Abstract
A communication terminal includes a crystal oscillator, a transceiver and circuitry. The crystal oscillator belongs to a specified type in which a dependence of an output frequency on temperature has one or more temperature dependence coefficients. The transceiver is arranged to operate an AFC loop having an initial frequency accuracy requirement that is more stringent than an uncompensated frequency accuracy of the crystal oscillator. The circuitry is arranged to determine output frequencies of the crystal oscillator at respective operating temperatures, to compute the temperature dependence coefficients based on the output frequencies and operating temperatures, to correct a frequency error in the output frequency using the dependence and the temperature dependence coefficients, to ascertain that the corrected frequency error meets the initial frequency accuracy requirement, and to subsequently correct a frequency of the received signal using the AFC loop.
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Citations
16 Claims
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1. A wireless communication terminal, comprising:
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a crystal oscillator, which belongs to a specified type of crystal oscillators in which a dependence of an output frequency as a function of temperature has one or more temperature dependence coefficients that vary among the crystal oscillators belonging to the specified type; a transceiver, which is arranged to operate an Automatic Frequency Control (AFC) loop having a frequency accuracy requirement for initial AFC synchronization that is more stringent than an uncompensated frequency accuracy of the given crystal oscillator; and circuitry, which is arranged to determine one or more output frequencies of the crystal oscillator at one or more respective operating temperatures, to compute the one or more temperature dependence coefficients for the crystal oscillator based on both of the one or more determined output frequencies and the one or more operating temperatures, to correct a frequency error in the output frequency of the crystal oscillator using the dependence and the computed temperature dependence coefficients in an initial AFC synchronization stage in which the AFC loop is unlocked, to ascertain, before receiving a signal to be tracked by the AFC loop, that the corrected frequency error meets the frequency accuracy requirement of the AFC loop, and, in a subsequent tracking stage, to lock the AFC loop on the received signal and to correct a frequency of the received signal using the locked AFC loop. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. A method for frequency control in a wireless communication device, the method comprising:
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determining one or more output frequencies of a given crystal oscillator at one or more respective operating temperatures, wherein the given crystal oscillator belongs to a specified type of crystal oscillators in which a dependence of the output frequency as a function of temperature has one or more temperature dependence coefficients that vary among the crystal oscillators belonging to the specified type; computing the one or more temperature dependence coefficients for the given crystal oscillator based on both of the two or more determined output frequencies and the two or more operating temperatures; operating an Automatic Frequency Control (AFC) loop having a frequency accuracy requirement for initial AFC synchronization that is more stringent than an uncompensated frequency accuracy of the given crystal oscillator; and correcting a frequency error in the output frequency of the given crystal oscillator at a measured operating temperature using the dependence and the computed temperature dependence coefficients in an initial AFC synchronization stage in which the AFC loop is unlocked, ascertaining, before receiving a signal to be tracked by the AFC loop, that the corrected frequency error meets the frequency accuracy requirement of the AFC loop, and, in a subsequent tracking stage, locking the AFC loop on the received signal and correcting a frequency of the received signal using the locked AFC loop. - View Dependent Claims (12, 13, 14, 15, 16)
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Specification