1. Technical Field
Aspects of this document relate generally to telecommunication systems and methods for signal interference cancellation for data transmission through a telecommunication channel.
2. Background Art
Conventional telecommunications systems utilize circuitry relating to interference cancellation such as that described in U.S. Publication No. 2002/0197958A1 (www.ptodirect.com/publication/?20020197958) which is herein incorporated by reference in its entirety. Conventional circuits have the following disadvantages:
U.S. Pat. No. 4,736,455, which is herein incorporated by reference in its entirety, includes another example of a conventional interference cancellation system. Like the above described conventional interference cancellation system, implementations of the present interference cancellation system may be used in multiple carrier frequency reuse communications systems, such as satellite communications systems.
Implementations of telecommunication systems like those disclosed in this document may include implementations of a system for removing interference from a composite received baseband signal comprising a receive decimation filter that accepts the composite received baseband signal and generates filtered sampled data at a decimation rate wherein the composite received baseband signal comprises a desired signal and an interfering signal, a transmit decimation filter that accepts a digitally converted replica of the interfering signal and generates filtered sampled data at a decimation rate and an integer sample delay control (ISDC) that provides multiple sample delay control for the replica of the interfering signal and stores an estimated delay value. The system further comprises an adaptive filter that provides fractional sample delay control for the replica of the interfering signal and optimizes cancellation of the interfering signal present in the composite received baseband signal, a digital phase-locked loop (DPLL) programmed with a known frequency offset of the interfering signal that tracks a phase and frequency of the replica of the interfering signal, an automatic gain control (AGC) that maintains near full scale operation of adaptive filtering and the DPLL, a slicer which is effectively a subtractor, and an error estimator which is formed by the slicer, a mixer and a delay unit.
Particular implementations may include one or more of the following. The estimated delay value corresponds to a delay difference between the interfering signal and the replica of the interfering signal. The DPLL is located after the adaptive filter. The adaptive filter uses a least mean square (LMS) algorithm and a finite impulse response (FIR) filter.
The integer sample delay control (ISDC) further comprises a computer readable medium that stores a complex sample of the replica of the interfering signal and a multiple sample delay control mechanism.
The computer readable medium uses double data rate synchronous dynamic random access memory (SDRAM) or any memory device capable of storing the sample data.
The adaptive filter further comprises a finite impulse response (FIR) filter. The FIR filter can be a real or complex FIR filter, and may be configured to switch between a real and a complex FIR filter.
The DPLL further comprises a phase detector that includes an arctangent function and a complex multiplier, a second order loop filter or a third order loop filter, an adder that accepts an initial frequency offset and an output of the loop filter, and a complex numerical controlled oscillator (NCO) that accepts a sum of the initial frequency offset and the output of the loop filter and provides a complex sinusoidal output.
The AGC further comprises an FIR coefficient calculator that sums the LMS coefficients and determines an absolute value of the sum, a subtractor that calculates a difference between the absolute value and a target gain, a multiplier to scale the difference, and an integrator that accumulates the scaled difference.
The error estimator further comprises a complex multiplier that accepts a complex conjugate of a delayed output of the complex NCO and an output of the slicer to update the LMS coefficients.
In another aspect, implementations of an interference cancellation may further provide for a method for removing interference from a composite received baseband signal comprising accepting, by a receive decimation filter, the composite received baseband signal wherein the composite received baseband signal comprises a desired signal and an interfering signal, generating, by the receive decimation filter, filtered sampled data at a decimation rate, and accepting, by a transmit decimation filter, a digitally converted replica of the interfering signal. The method further comprises generating, by a the transmit decimation filter, filtered sampled data at a decimation rate, providing, by an integer sample delay control (ISDC), multiple sample delay control for the replica of the interfering signal, storing, by the integer sample delay control (ISDC), an estimated delay value, providing, by an adaptive filter, fractional sample delay control for the replica of the interfering signal, optimizing, by the adaptive filter, cancellation of the interfering signal present in the composite received baseband signal, tracking, by a digital phase-locked loop (DPLL) that is programmed with a known frequency offset of the interfering signal, a phase and frequency of the replica of the interfering signal, maintaining, by an automatic gain control (AGC), near full scale operation of adaptive filtering and the DPLL, and updating an adaptive filter coefficient by an error estimator having a conjugate multiplier and a slicer.
Particular implementations may include one or more of the following. The estimated delay value corresponds to a delay difference between the interfering signal and the replica of the interfering signal. The DPLL is located after the adaptive filter. A least mean square (LMS) algorithm and a finite impulse response (FIR) filter is used. The adaptive filter further comprises a finite impulse response (FIR) filter. The FIR filter can be a real or complex FIR filter, and may be configured to switch between a real and a complex FIR filter. The method further comprises storing by the integer sample delay control (ISDC) on a computer readable medium, a complex sample of the replica of the interfering signal and providing a multiple sample delay control mechanism.
The method further comprises using, by the computer readable medium, double data rate synchronous dynamic random access memory (SDRAM) or any memory device capable of storing sample data.
The adaptive filter further comprises a finite impulse response (FIR) filter. The FIR filter can be a real or complex FIR filter, and may be configured to switch between a real and a complex FIR filter. The tracking by the DPLL further comprises detecting a phase using an arctangent function and a complex multiplier, determining estimated loop parameters based on a sampling rate for a second order loop filter or a third order loop filter, accepting, by an adder, an initial frequency offset and an output of the loop filter, accepting, by a complex numerical controlled oscillator (NCO), a sum of the initial frequency offset and the output of the loop filter; and providing, by the complex NCO, a complex sinusoidal output.
Maintaining, by an automatic gain control (AGC) further comprises summing, by an FIR coefficient calculator, the LMS coefficients, determining, by the FIR coefficient calculator, an absolute value of the sum, calculating, by a subtractor, a difference between the absolute value and a target gain, scaling the difference by a multiplier; and accumulating, by an integrator, the scaled difference.
Updating an adaptive filter coefficient by the error estimator further comprises accepting, by a complex multiplier, a complex conjugate of a delayed output of the complex NCO and an output of the slicer to update the LMS coefficients.
The foregoing and other aspects, features, and advantages will be apparent to those artisans of ordinary skill in the art from the DESCRIPTION and DRAWINGS, and from the CLAIMS.
Implementations will hereinafter be described in conjunction with the appended drawings, where like designations denote like elements, and:
This disclosure, its aspects and implementations, are not limited to the specific components or assembly procedures disclosed herein. Many additional components and assembly procedures known in the art consistent with the intended interference cancellation system and/or assembly procedures for a telecommunication system using interference cancellation will become apparent for use with particular implementations from this disclosure. Accordingly, for example, although particular implementations are disclosed, such implementations and implementing components may comprise any shape, size, style, type, model, version, measurement, concentration, material, quantity, and/or the like as is known in the art for such telecommunication systems using interference cancellation and implementing components, consistent with the intended operation.
Implementations of interference cancellation systems as provided in this disclosure improve the performance of conventional interference cancelling systems and may be implemented with the use of a field-programmable gate array (FPGA), digital signal processor (DSP), or general purpose processor which is capable of using most digital signal processing techniques.
It is assumed that the initial delay and frequency offset estimations of the undesired signal relative to its replica are known. These initial parameters can be determined using some known algorithms found in literatures, such as described by Stein, “Algorithms for Ambiguity Function Processing”, IEEE Transactions on Acoustics, Speech, and Signal Processing, Vol. ASSP-29, No. 3, pp 588-599, June 1981, which is hereby incorporated entirely by this reference.
Implementations of the interference cancellation systems disclosed herein may operate on baseband or near baseband signals wherein analog signals are converted to digital samples for signal processing. The cancellation of the interfering signal from the composite received signal employs digital signal processing (DSP) techniques such as adaptive filtering or equalization, which can be easily implemented in FPGA's, DSP's, or a general purpose processor.
This disclosure also provides a method and system for canceling the interfering signal from the composite received signal containing the undesired signal and desired signal, wherein the digital phase-locked loop (DPLL) does not intervene with the adaptive equalizer in terms of phase tracking capability and delay tracking capability. Hence it improves delay tracking performance at high Doppler rate of change for satellite applications. It also allows use of the real adaptive filter instead of the complex one if applicable in a particular application, which substantially reduces the required resource.
In other aspects, this disclosure provides for a method and system for improving the cancellation performance by providing automatic gain control (AGC) that is driven by the adaptive filter (or LMS equalizer) in order to operate nearly full scale in digital form.
Unlike conventional interference cancellation systems, this disclosure and related implementations may be embedded in a digital communications system containing a modulator and demodulator such as a satellite modem as shown in
The ISDC 3 stores an initial delay estimate and delays the interference signal in integer multiple samples during operation. The FSDC 4 may use a least mean square (LMS) adaptive equalizer to track fractional sample delay wherein the delay is less than one sample. It consistently monitors the mass center of the LMS finite impulse response (FIR) coefficients' power. When the mass center has shifted by one tap or more, FSDC 4 signals ISDC 3 to advance or delay the interference signal by one sample and shifts the LMS coefficients accordingly to accommodate this shift in the interference signal. This event is called delay handover.
As shown in
Another advantage of locating the DPLL 5 after the FSDC 4 is that the FSDC 4 may use a real adaptive equalizer if a complex adaptive equalizer is unnecessary in particular applications, which is impossible in the conventional circuits of the prior art. This is advantageous because a real adaptive equalizer uses far fewer resources than a complex adaptive equalizer.
The DPLL 5 may be a second-order or third-order loop, depending on the particular applications, and its initial frequency estimate is assumed to be loaded prior to running the digital phase-locked loop (DPLL). The DPLL phase detector uses a complex multiplier with one complex conjugate input from the rotated FSDC output and another complex input from composite received signal, and an arctangent function. It is possible to provide low-pass filtered or smoothed samples before and/or after the arctangent function. The DPLL lock is used as an indication of the canceller lock.
The purpose of the AGC 6 is, among other things, to isolate the processing signal level before the slicer from the composite received signal level, so that the adaptive equalizer in the FSDC 4 and DPLL 5 can operate at a selectable, desired level, which is as near full scale as possible. It accomplishes this goal by maintaining the adaptive equalizer gain at a selectable, desired level. It substantially improves the cancellation performance and contributes to the increasing delay tracking capability. In a particular implementation, near full scale is typically at about 70% of full scale, but may be set higher or lower depending upon the needs of particular applications.
As illustrated in
The ISDC 3 delays the interference by integer multiple samples. The initial delay is estimated and loaded. During operation, when it receives Advance (adv) signal from the fractional sample delay control (FSDC), it reduces the delay by one sample. On the other hand, when the ISDC receives Delay (dly) signal from the FSDC 4, it increases the delay by one sample.
As shown in
The following derivation shows how the LMS coefficients or weights should be updated with introduction of Mixer 18 and Gain Controller 12. For simplicity of derivation, the delay in Mixer 1, Gain Controller, and Slicer have been omitted.
y
n
=W
n-1
T
X
n Equation 1
e
n
=d
n−αnynejnΩ=dn−Wn-1TXn(αnejnΩ) Equation 2
Where αn is the AGC gain, and Xn and Wn are the input and LMS weight vectors, respectively:
X
n=(xnxn-1 . . . xn-(L-1))T Equation 3
W
n=(w0,nw1,n . . . wL-1,n)T Equation 4
L is the number of the LMS taps. Now the input to the complex LMS can be treated as Zn:
Z
n
=X
n(αnejnΩ) Equation 5
e
n
=d
n−αnynejnΩ=dn−Wn-1TZn Equation 6
Then the weight update becomes that
To simplify implementation and save resource, the LMS weight update can be done with the sign of en as long as the adaptation constant μ is smaller enough. Because AGC gain αn is real and positive, αn en doesn't change the sign of en. Therefore,
W
n
=W
n-1+μ(αnene−jnΩ)X*n=Wn-1+μ(ene−jnΩ)X*n=Wn-1+μvnX*n Equation 8
Where vn is the input to the FSDC as shown in
v
n
=e
n
e
−jnΩ Equation 9
The offset center of mass (CoM) of the FIR coefficients' power is calculated as
CoM takes values between +/−0.5(L−1). If CoM<0, delay leans towards decreasing. If CoM>0, delay leans toward increasing. When CoM<=−1, Block 4.3 generates Advance and Wn shifts down by one tap. When CoM>=1, it generates Delay and Wn shifts up by one tap.
In hardware implementation, it is likely that pipeline exists to increase the processing speed. Therefore, pipeline is likely introduced in Mixer 1, Gain Controller and Slicer. The LMS algorithm requires exactly match in sample delay. This is the purpose of Delay Units 1 and 2 as shown in
Though the main function of the adaptive equalizer is to track fractional delay (delay less than one sample), the complex adaptive equalizer can also compensate linear distortion in the interference in the composite received signal. However, in applications where the linear distortion is minimal, the compensation may not be necessary. In that case, a real adaptive equalizer can be used instead of a complex adaptive equalizer. The real adaptive equalizer uses only half the multipliers that the complex one of the same impulse response length uses, resulting in saving substantial resources in implementation.
If the real adaptive equalizer is used, Wn is a real vector and its update is defined as
W
n
=W
n-1
+μRe(vnX*n) Equation 11
In summary, the FSDC algorithm is as follows.
LMS FIR Block:
y
n
=W
n-1
T
X
n Equation 12
Complex LMS Coefficient Update Block:
W
n
=W
n-1
+μv
n
X*
n Equation 13
Real LMS Coefficient Update Block:
W
n
=W
n-1
+μRe(vnX*n) Equation 14
Advance adv=1, shift down:
W
n=(0w0,n-1 . . . wL-2,n-1)T Equation 15
Delay dly=1, shift up:
W
n=(w1,nw2,n . . . wL-1,n0)T Equation 16
The DPLL is a typical digital phase-locked loop having Phase Detector 5.1, Loop Filter 5.2, Complex NCO 5.3, PLL Lock Detection 5.4, and Initial Frequency Estimation 5.5 as shown in
One implementation of the phase detector is shown in
c
n
=d
n
u*
n Equation 17
The real and imaginary parts of cn run through two identical low pass filters, respectively, in the Low Pass Filter block 5.1.1. The complex output gn runs through an arctangent function 5.1.2 to calculate the phase difference qn between dn and un. qn can run through another low pass filter 5.1.3 to further smooth the phase difference as output pn.
One commonly used PLL lock detection method is to average the absolute value of the phase detector output. When the PLL is locked, the average absolute value of the phase detector output is relatively small and thus, can be used as PLL lock indication when the average absolute value is below a predetermined threshold.
The AGC as shown in
The LMS FIR gain calculation 6.1 is defined by Equation 18.
The AGC gain αn is updated by Equation 19 as seen in
αn=αn-1+μa(Gn−Gt) Equation 19
Where Gt is the target LMS FIR gain 6.2 and μa is the AGC constant controlling how sensitive the AGC gain αn is to the LMS FIR gain change prior to reaching the Integrator 6.3. The AGC constant μa should be less than 10% of the LMS adaptation constant μ to avoid disturbance to the LMS adaptation.
When using a configuration that allows use of a real adaptive equalizer, the LMS equalizer can be configured as switchable between real FIR and complex FIR as shown in
As shown in
In places where the description above refers to particular implementations of adaptive interference cancellation systems, it should be readily apparent that a number of modifications may be made without departing from the spirit thereof and that these implementations may be applied to other telecommunication systems having adaptive interference cancellation systems.
This document is a continuation application of U.S. patent application Ser. No. 12/778,032, entitled “Fully Compensated Adaptive Interference Cancellation System” to Lianfeng Peng et al. which was filed on May 11, 2010, now pending, which application claims the benefit of the filing date of U.S. Provisional Patent Application No. 61/177,231, entitled “Fully Compensated Adaptive Interference Cancellation System” to Lianfeng Peng et al. which was filed on May 11, 2009, the disclosures of which are hereby incorporated entirely herein by reference.
Number | Date | Country | |
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61177231 | May 2009 | US |
Number | Date | Country | |
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Parent | 12778032 | May 2010 | US |
Child | 13686316 | US |