The present invention relates to frequency tracking at a mobile station for use in a wireless communications environment, and more particularly, using information derived from the recovered data at the receiver of the mobile station to tune a reference local voltage controlled oscillator (VCO).
In a wireless communications system, the air interface typically involves a mobile station communicating with a base station over the airwaves. For example, the most common standard for wireless communications in the world is the Global System for Mobile communications (GSM). In one specific implementation, GSM utilizes two bands of 25 MHz, which have been set aside for system use. The 890-915 MHz band is used for mobile station to base station transmissions (reverse link), and the 935-960 MHz band is used for base station to mobile station transmissions (forward link). The GSM protocol uses frequency division duplexing and time division multiple access (TDMA) techniques to provide base stations with simultaneous access to multiple users. Transmissions on both the forward and reverse link are made at a channel data rate of 270.833333 Kbps, using binary Gaussian Minimum Shift Key (GMSK) modulation. Additionally, each link contains traffic channels and control channels. The traffic channels carry the digitized voice or user data. The control channels carry network management or control information such as the frequency correction channel (FCCH).
When a mobile station is powered on, it must first perform a power scan across all the control channels, to identify the channel with the strongest signal. The mobile station then tunes into the strongest channel to locate the FCCH. FCCH carries a frequency correction burst, which occupies time slot 0 for the very first GSM frame and is repeated every ten frames within a control channel multiframe. The FCCH burst allows each mobile station to synchronize its reference local oscillator or voltage controlled oscillator (VCO) to the exact frequency of the base station.
However, the VCO in a mobile station is usually not as robust as the VCO at the base station. Consequently, the frequency will fluctuate with the temperature of the VCO, in addition to other factors, such as aging, that will also contribute to the fluctuation but in a less significant amount. The frequency fluctuation will accumulate over time resulting in degrading the performance of the mobile station's receiver. An automatic frequency control (AFC) subsystem is an important component of a receiver for performance stability. For example, the GSM 11.10 specification requires a mobile station to maintain a carrier frequency to within 0.1 parts per million (ppm) of the base station's reference frequency, in other words, 0.1 ppm compared to the signals received from the base station. Although, the prior art Maximum Likelihood method can be used to obtain reliable frequency tracking, but it requires a long data stream and complex computation. Similarly, the prior art Time Domain Bias method can also be deployed for estimating frequency offset, but it needs a high sampling rate as well as a long data stream. Accordingly, the AFC subsystem in the receiver of a mobile station needs a reliable, simple, and effective frequency tracking technique to minimize frequency error to an acceptable level.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
In the detailed description provided below, numerous specific details are provided to impart a thorough understanding of embodiments of the invention. One skilled in the relevant art will recognize, however, that the invention can be practiced without one or more of the specific details, or with other methods, components, materials, etc. In other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of the invention.
Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
In accordance with the linear approximation of GMSK modulation, pk 106 is mathematically represented as:
pk=ak·jk
where ak is the outgoing data and ak is either 1 or −1. k is the data index. jk is the modulation phase shift.
h(t)=f(t)*ch(t)
where f(t) is filter f(t) 108 and ch(t) is air channel ch(t) 110.
When incoming data y(t) 114 arrives at the receiver, it is first demodulated and then a frequency offset is added to the demodulated data. The resulting received data is r(k). The frequency offset here does not take into account any frequency offset that may be caused by Doppler shift because Doppler shift cannot be tracked in mobile communications and it is not required by the GSM specification. The received data r(k) is mathematically represented as:
r(k)=y(k)·ejωk
where ejωk is the frequency offset, ω is the angle of the frequency offset and k is the data index.
A key component of a mobile station receiver is the AFC subsystem. The AFC contains a frequency tracking mechanism to ensure that the frequency of the mobile station's local VCO tracks the frequency of the base station.
Prior to frequency tracking, initial frequency estimation is performed on the received data r(k) 304 to obtain the estimated channel tap ĥ(k) 308. The channel is estimated by a training sequence in p(k). The estimated channel tap ĥ(k) 308 is mathematically represented as:
where k=−5, −4, . . . , 0, 1, . . . , 5. The frequency offset has a negligible affect on the channel estimation in the range of −500 Hz to 500 Hz. Thus, the weak taps of the estimated channel taps can be masked.
In one embodiment as illustrated in
In another embodiment also depicted by
For each data burst the direction of the phase rotation is determined based on the frequency error. Within a given number of data bursts, the number of positive direction rotations and the number of negative direction rotations are calculated. If the number of positive direction rotations within the given number of data bursts is greater than a predetermined threshold, then the local VCO of the mobile station is tuned one frequency step in the negative direction. If the number of negative direction rotations within the given number of data bursts is greater than a predetermined threshold, then the local VCO of the mobile station is tuned one frequency step in the position direction.
Turning first to
Next, in step 508 the result of the first correlated data is delayed. In step 510, a second correlation is performed on the first correlated data of step 506 with the delayed first correlated data of step 508. The second correlation provides the rotation angle caused by the frequency offset. The second correlated data is added to the imaginary part of the second correlated data in step 512. If the result of the sum in step 512 is positive, then the positive register is increased by one. If the result of the sum in step 512 is negative, then the negative register is increased by one. Steps 502 through step 518 are then repeated for N data bursts.
After N data bursts are reached in step 520, if the positive register is greater than the predetermined threshold, then the VCO is tuned one step in the negative direction in step 524. Otherwise, if the negative register is greater than the predetermined threshold, then the VCO is tuned one step in the positive direction in step 526. Finally, in step 530 the positive register and the negative register are cleared.
{circumflex over (p)}k=âk·jk
The rotated estimated input {circumflex over (p)}(k) passes through the estimated channel tap ĥ(k) 308 to get the recovered data {circumflex over (r)}(k) 404. The recovered data {circumflex over (r)}(k) 404 is mathematically represented as:
{circumflex over (r)}(k)={circumflex over (p)}(k)*ĥ(k)=ŷ(k)
A first correlation 406 is performed on the received data r(k) 304 and the recovered data {circumflex over (r)}(k) 404 to obtain the first correlated data z(k) 410. The first correlated data z(k) 410 is mathematically represented as:
z(k)=r(k)·conj({circumflex over (r)}(k))=(y(k)·ejωk+n(k))·conj(ŷ(k))≈|y(k)|2·ejωk+n′(k)
where ω is the angle of the frequency offset, k is the data index, and ·n′(k)=n(k)·conj(ŷ(k)).
A second correlation 414 is performed on the first correlated data z(k) 410 and the delayed first correlated data z(k+L) 412, where L is the delayed sample, which is set to adjust the rotation angle in a range to obtain a more precise estimation.
The resulting second correlated data s′(k) 416 is mathematically represented as:
s′(k)=z(k+L)·conj(z(k))
The mathematical representation of the imaginary part of s′(k) is:
s(k)=imag{z(k+L)·conj(z(k))}
Add the imaginary part s(k) to the second correlated data s′(k) 416 to obtain d 420. The mathematical representation of d 420 is:
where M is the length of s(k).
The decision 422 mechanism counts the number of d>0 and the number of d<0 within every N data bursts. If the number of d>0 is greater than a predetermined threshold, the VCO is tuned one frequency step in the negative direction. If the number of d<0 is greater than a predetermined threshold, the VCO is tune one frequency step in the position direction.
The parameters for a mobile station in a GSM communications system based on the GSM 11.10 requirements in one example may be as follows: L=100; M=40; N can be 100 or 200 received data bursts; and predetermined threshold can be larger than half of N.
While specific embodiments of the invention have been illustrated and described herein, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.
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