Zero-IF transmitter employs homodyne or direct up-conversion to transmit a pair of quadrature signals, i.e., signals that differ in phase by 90 degrees. The reference signal of the pair of quadrature signals, which is “in-phase,” is referred to as I signal. The signal that is shifted 90 degrees, and is in “quadrature” phase, is referred to as Q signal. During the homodyne up-conversation, the I and Q baseband signals are mixed with the in-phase and quadrature-phase components of a local oscillator (LO) signal to generate I and Q RF signals for transmission.
During a direct up-conversion, it is important to maintain the amplitude relationship between the I and Q signals after the mix to ensure an accurate signal transmission. It is also important to maintain the phase relationship between the in-phase and quadrature-phase components of the local oscillator to prevent a phase skew. In reality, however, errors such as an IQ gain/phase imbalance existing in a zero-IF transmitter impairs the amplitude relationship and the phase relationship between the I and Q RF signals, resulting in images of transmitted signal reflected about the local oscillator frequency. Furthermore, DC offset in the I and Q RF signals prior to up-conversion may result in a spurious tone signal at the local oscillator frequency
A correction is attempted before the IQ baseband signals are mixed with the in-phase and quadrature components of the local oscillator to compensate for errors such as the IQ imbalance or DC offset. To determine the correction, a zero-IF transmitter output is fed back to a feedback receiver chain, and the output of the feedback chain is observed. The determination of the correction, however, is based on channel response characteristics (from transmitter to feedback chain output), which vary from frequency to frequency and not readily determinable.
An aspect of the present invention provides a channel estimation system comprising a calibrating signal generator configured to generate at least one pair of calibrating signals, a feedback IQ mismatch estimator configured to measure feedback IQ mismatch estimates based on the pair of calibrating signals, and a calibrating signal based channel estimator configured to generate a channel estimate based on the pair of calibrating signals and the feedback IQ mismatch estimates.
Another aspect of the present invention provides a channel estimation system comprising a traffic signal based channel estimator configured to estimate a channel response estimation corresponding to a frequency of an input baseband traffic signal, a calibrating signal generator configured to generate a calibrating signal based on the channel response estimation by the traffic signal based channel estimator, and a correction filter configured to compensate a subsequent input baseband traffic signal to cancel an image signal of the subsequent input baseband traffic signal based on the calibrating signal.
Another aspect of the present invention provides a channel estimation system comprising, a calibrating signal generator configured to generate at least one pair of calibrating signals from which a channel response is estimated, a feedback direct current (DC) estimator configured to measure feedback DC estimates based on the pair of calibrating signals, a transmitter DC estimator configured to measure DC levels of the channel estimation system, and a calibrating signal based channel estimator configured to generate a channel estimate based on the pair of calibrating signals, feedback DC estimates and the measured DC levels.
For a detailed description of various examples, reference will now be made to the accompanying drawings in which:
In the following detailed description, reference is made to certain examples of the present invention. These examples are described with sufficient detail to enable those skilled in the art to practice them. It is to be understood that other examples may be employed and that various structural, logical, and electrical changes may be made. Moreover, while specific examples are described in connection with a zero-IF transmitter, it should be understood that features described herein are generally applicable to other types of electronic parts, circuits, or transmitters.
In this description, the term “couple” or “couples” means either an indirect or direct wired or wireless connection. Thus, if a first device couples to a second device, that connection may be through a direct connection or through an indirect connection via other devices and connections. For another instance, when a first device is coupled to a second device, the first and second device may be coupled through a capacitor. The recitation “based on” means “based at least in part on.” Therefore, if X is based on Y, X may be a function of Y and any number of other factors.
Signals S2, S3, and S4 are frequency domain signals observed by a receiver after the zero-IF transmitter of
Signals S5, S6, and S7 are signals measured at an end of feedback chain 130 after the transmit signals S2, S3, and S4 are fed back. Signal S5 corresponds to signal S2, signal S6 to signal S3, and signal S7 to signal S4. Tx-IQ/LO estimator 140 estimates a channel response based on signals S1 and S5-S7, and further estimates IQ mismatch for a respective frequency and LO leakage. Based on the IQ mismatch estimates and LO leakage, Tx-IQ/LO estimator 140 provides a IQ mismatch correction function Hcorr(f) and LO leakage correction function LOcorr to Tx-IQM corrector 105 and Tx-LO leakage corrector 110, respectively. Tx-IQM corrector 105 and Tx-LO leakage corrector 110 adjust signal S1 to compensate for IQ mismatch and LO leakage during transmission based on Hcorr(f) and LOcorr.
Graph of
The three signals are signal AHCH(f1), signal DC and signal A*HIQ(−f1), as shown in graph 1(b). Signal AHC(f1) corresponds to the original signal X(f) with frequency f1, where HC(f1) is a channel response at frequency f1. Signal DC corresponds to the leaked local oscillator signal of frequency fLO. Signal A*HIQ(−f1) corresponds to an image signal of negative frequency −f1 due to the IQ mismatch of the zero-IF transmitter.
To compensate for an IQ mismatch and LO leakage, the zero-IF transmitter may adjust signal X(f) to cancel signal A*HIQ(−f1) and signal DC during transmission. To adjust a signal to compensate the changes due to an IQ mismatch and LO leakage, however, the transmitter-to-feedback chain channel response at a frequency corresponding to the image signal and LO leakage must be estimated. The feedback signals based on an input signal X(f1) is used to estimate a channel response at frequency f1, by performing a frequency domain cross correlation of components of transmitter and feedback baseband data falling at f1, but not for the channel responses at a frequency corresponding to the image signal and LO leakage.
According to an aspect of the present invention, calibrating signals are generated and transmitted to determine channel responses at a frequency corresponding to the image signal. In one example, a first calibrating signal based on a baseband signal with frequency f1 may be transmitted, followed by a second calibrating signal based on the baseband signal with frequency f1. The first and second calibrating signals are each transmitted at different time slots, preferably consecutively. First and second feedback signals, each corresponding to the first and second calibrating signals, are measured. An aspect of the present invention determines a channel response corresponding to frequency −f1 based on the first and second feedback signals.
According to another aspect of the present invention, calibrating signals are generated and transmitted to determine channel response at a frequency corresponding to LO leakage. In one example, a first calibrating signal and a second calibrating signal are generated. The first and second calibrating signals are each transmitted at different time slots, preferably consecutively. First and second feedback signals, each corresponding to the first and second calibrating signals, are measured. An aspect of the present invention determines a channel response corresponding to the LO leakage based on the first and second feedback signals.
Below, examples of various aspects of the present invention are further described with an exemplary figure of the examples.
X
C1(f)=ΔX*B(−f); Eq. 1.
X
C2(f)=−ΔX*B(−f); Eq. 2.
Calibrating signals XC1(f) and XC2(f) are generated non-simultaneously—the signals are generated consecutively. To generate calibrating signals XC1(f) and XC2(f), calibrating signal generator 315 comprises a conjugate translator to generate a conjugate signal of a baseband signal XB(f).
In equations 1 and 2, Δ is a random constant. In another example, Δ may be a function of a frequency (e.g., Δ(f)), which allows calibrating signal generator 315 to generate a calibrating signal of a specific frequency. In another example, XC1(f) is Δ1X*B(−f) and XC2(f) is Δ2X*B(−f), where Δ1 and Δ2 are each random constant. In another example, the magnitude of Δ is proportional to residual IQ mismatch image level, i.e., the uncorrected IQ mismatch image level.
Signals XC1(f) and XC2(f) are consecutively up-converted by mixer 320, which uses a mixing frequency generated by local oscillator 321, and further amplified by power amplifier 325 for transmission. Mixer 330 in the feedback chain down-converts the signal outputs from power amplifier 325, based on a mixing frequency generated by local oscillator 331.
Traffic signal based channel estimator 335 performs a frequency domain correlation of a baseband traffic signal with a down-converted signal output from mixer 330 to determine a channel response corresponding to the baseband signal frequency. For instance, in
Feedback IQ mismatch estimator 340 measures feedback signals based on the two calibrating signals XC1(f) and XC2(f), and generates corresponding frequency domain IQ mismatch estimates by performing a frequency domain correlation of a transmitted signal and a fed-back signal at a respective frequency. For example, IQ mismatch estimate HIQ(−f) is measured by performing a frequency domain correction of a transmitted signal component at frequency ‘f’ with a feedback signal component at frequency ‘−f.’
Pursuant to equations 1 and 2 noted above, the two calibrating signals are generated, in series in different times, by calibrating signal generator 315, up-converted and down-converted by mixers 320 and 330, and fed into feedback IQ mismatch estimator 340, in series. Based on the feedback signals, feedback IQ mismatch estimator 340 generates IQ mismatch estimates for each calibrating signal. For example, feedback IQ mismatch estimator 340 generates IQ estimate HIQ1(f), an IQ mismatch estimate based on a fed-back signal measured by feedback IQ mismatch estimator 340 after first calibrating signal XC1(f) is transmitted. Feedback IQ mismatch estimator 340 further generates IQ estimate HIQ2(f), an IQ mismatch estimate based on a fed-back signal measured by feedback IQ mismatch estimator 340 after second calibrating signal XC2(f) is transmitted.
Based on IQ estimates HIQ1(f) and HIQ2(f), calibrating signal based channel estimator 345 estimates a channel response corresponding to the image signal of the baseband signal XB(f) according to equation 3 below.
H
CH(f)=(HIQ2(f)−HIQ1(f))/2Δ. Eq. 3.
In the example of
H
CORR(−f1)=HIQ(−f1)/HCH(−f1). Eq. 4.
In other words, by applying the HCORR(−f1) generated by correction filter term generator 360, correction filter 310 adjusts a subsequent baseband signal with frequency f1 to cancel out an image signal caused by an IQ mismatch.
The example of
X
B(f)+ΔX*B(−f), Eq. 5.
X
B(f)−ΔX*B(−f), Eq. 6.
Optionally, the example of
For instance, where a baseband traffic signal of frequency f1 is transmitted, traffic signal based channel estimator 335 generates a channel estimate for frequency f1. If channel history tracker 350 does not store a corresponding image signal channel estimate, i.e., channel estimate for frequency −f1, however, calibrating signal controller 315 controls calibrating signal generator 315 to generate a pair of calibrating signal to enable channel estimation at −f1. For instance, the pair of calibrating signals may be, XC1(−f1)=ΔX*B(f1) and XC2(−f1)=−ΔX*B(f1).
Based on the pair of calibrating signals, calibrating signal based channel estimator 345 generates a channel estimate for frequency −f1, based on equation 3. The channel estimate for frequency −f1 is stored in channel history tracker 350 for further use.
In the state machine diagram of
The state machine diagram starts from state S1 where calibrating signal controller 315 determines that not all relevant channel response is stored in channel history tracker 350 and there is a need to estimate a channel response at a frequency. In such case, the signal transmitter of
If not all relevant channel response is estimated, however, the signal transmitter of
However, if calibrating signal controller 315 determines not all relevant channel response is estimated, the signal transmitter of
If valid feedback signals were received by the signal transmitter of
If all relevant channel response is estimated in state S4, the signal transmitter of
In
In another example, after the first pair of calibrating signals are generated according to equations 1 and 2, or after an image signal channel estimate is determined based on the calibrating signals, calibrating signal generator 315 stops to generate additional calibrating signals.
Calibrating signal controller 355 may later control calibrating signal generator 315 to again generate a pair of calibrating signal. For instance, after a pre-determined set of time has lapsed or the channel estimation system of
The channel estimation system of
In one example, the tones generated by calibrating signal generator 510 is based on a channel response estimation generated by traffic signal based channel estimator 503. In the example of
Calibrating signal controller 506 determines a need for a channel response estimation according to a state machine similar to the state machine of
The output of adder 541 is fed into correction filter 501. Based on the output of adder 541, correction filter 501 pre-neutralizes or pre-cancels out an image signal from the input signal XB(f). In other words, correction filter 501 pre-cancels out a projected image signal, based on the calibrating signal XC(f), so that an image signal is canceled out from the signal output from power amplifier 530 for transmission.
X
C11(f)=Δ1; Eq. 7.
X
C12(f)=Δ2. Eq. 8.
In one example, Δ2 may be −Δ1.
Calibrating signals XC11(f) and XC12(f) are generated non-simultaneously—the signals are generated consecutively at different time slots. Signals XC11(f) and XC12(f) are consecutively up-converted by mixer 620, based on a mixing frequency generated by local oscillator 621, and further amplified by power amplifier 625 for transmission. Mixer 630 down-converts the signal outputs from power amplifier 625, based on a mixing frequency generated by local oscillator 631.
Feedback DC estimator 640 measures feedback signals, each based on a respective one of the two calibrating signals XC11(f) and XC12(f), and generates corresponding feedback DC estimates, FBDC11, FBDC12. In one example, feedback DC estimates, FBDC11, FBDC12, are measured by performing a DC-level estimation (e.g., low pass filter) on the respective feedback signals. Feedback DC estimate FBDC11 is based on calibrating signal XC11(f) and a fed-back signal thereof. Feedback estimate FBDC12 is based on calibrating signal XC12(f) and a fed-back signal thereof.
TX DC estimator 646 measures DC levels in the transmit baseband signal and forwards the measurements to calibrating signal based channel estimator 645. TXDC11 represents DC levels measured when calibrating signal XC11(f) is transmitted. TXDC12 represents DC levels measured when calibrating signal XC12(f) is transmitted.
Calibrating signal based channel estimator 645 estimates a channel response at a frequency corresponding to a local oscillating frequency based on feedback DC estimates FBDC1 and FBDC2 and DC levels measured by TX DC estimator 646 according to equation 9 below.
H
CH(0)=(FBDC12−FBDC11)/[(Δ2−Δ1)+(TXDC12−TXDC11)] Eq. 9.
Correction filter term generator 660 generates filter term for correction filter 610 to correct LO leakage based on channel estimate at LO leakage frequency. The filter term generated by correction filter term generator 660 is further based on the DC levels TXDC measured by TX DC estimator 646 of the time of the filter term generation. The filter term generated, which comprises LO leakage correction term in
LO
CORR
=FB
DC
/H
CH(0)−TXDC Eq. 10.
In an example, correction filter 610 may simply perform an add or subtract function. In such case, correction filter 610 may comprise a simple add or subtract module, and correction filter term generator 660 may comprises a correction term generator generating LO leakage correction term according to equation 10 and providing the generated result to the add or subtract module.
Optionally, the calibrating signal generator 615 of
Similar to the example of channel estimation system of
For example, channel history tracker 650 stores channel estimate generated from calibrating signal based channel estimator 645. Where no corresponding LO leakage channel estimate is stored in the channel history tracker 650, calibrating signal controller 655 controls calibrating signal generator 615 to generate a pair of calibrating signal from which a LO leakage channel estimate be derived pursuant to above equations 7˜11.
Further, calibrating signals are generated by calibrating signal generator 615 only where calibrating signal controller 655 determines a need for a channel response estimation according to a state machine similar to the state machine of
Calibrating signal controller 655 may later control calibrating signal generator 615 to again generate a pair of calibrating signal. For instance, after a pre-determined set of time has lapsed or the channel estimation system of
According to yet another example of the present invention, the operations of channel estimation system of
The above description and drawings are only to be considered illustrative of an example of the present invention which achieves the features and advantages described herein. Modifications are possible in the described examples, and other examples are possible, within the scope of the claims. Accordingly, the examples of the present invention described herein is not considered as being limited by the foregoing description and drawings.
Number | Date | Country | Kind |
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201841044799 | Nov 2018 | IN | national |
This application claims priority to Indian Provisional Application No. 201841044799, filed on Nov. 28, 2018, and U.S. Provisional Application No. 62/786,496, filed on Dec. 30, 2018, which are hereby incorporated by reference.
Number | Date | Country | |
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62786496 | Dec 2018 | US |