JP4436217B2 - Ripple characteristic correction circuit and ripple characteristic correction method - Google Patents

Description

  The present invention relates to a ripple characteristic correction circuit and a ripple characteristic correction method.

It has been conventionally known that a ripple in the baseband band (a signal amplitude varies depending on a signal frequency) exists when a spread spectrum modulation signal for communication passes through a circuit. Conventionally, ripple is considered to be one of the indicators of circuit performance, so in order to obtain a circuit with little influence of ripple, a trimmer capacitor for correcting the ripple component in advance is provided at the circuit input stage. When the product including the circuit is installed and shipped, the ripple of the circuit is measured to adjust the capacitance of the trimmer capacitor to minimize the product ripple. This principle is described in detail in Non-Patent Document 1, for example.
Koichi Shimoda, Shinkai Sakurai, “Basics of Electronics (New Edition)”, Physics Selection 1, Kasuga Sobo, March 25, 1987, P.A. 254-255

  However, recently, high accuracy is often required for the amplitude component of the baseband signal of a circuit. For example, when quadrature amplitude modulation is performed in a communication device, extremely accurate amplitude control is required to identify communication signals multiplexed by amplitude. In this way, even if settings are made so that ripples are kept to a minimum at the time of shipment by the conventional method described above, the effects of slight changes in ripples due to the external environment such as temperature and humidity have been considered so far. Increasingly, such a slight change in ripple cannot be ignored.

  The present invention has been made in view of the above problems, and an object of the present invention is to make it possible to correct the ripple characteristics of the circuit at any time, thereby further reducing the influence of the ripple in the circuit. To provide a ripple characteristic correction circuit and a ripple characteristic correction method.

  The present invention for solving the above problems is a ripple characteristic correction circuit for correcting a ripple indicating an amplitude change of an output signal due to a frequency change of an input signal in a signal processing circuit, and each of the signal processing circuits includes: Amplitude detector calibration signal input means for inputting a plurality of amplitude detector calibration signals having different amplitudes in a predetermined order, and a plurality of ripple measurement signals having different frequencies are input to the signal processing circuit in a predetermined order. Ripple measurement signal input means, amplitude acquisition means for measuring the amplitude detector calibration signal and ripple measurement signal output from the signal processing circuit, and amplitude acquired by the amplitude acquisition means. And a ripple calculating means for calculating a feature amount of a ripple generated in the signal processing circuit.

  By doing so, it is possible to detect ripples without using a special measurement device, so that the ripples in the circuit can be corrected at any time using the detection results, and the effects of ripples in the circuit can be further improved. It becomes possible to reduce.

  Further, in the ripple characteristic correction circuit, the correlation between the amplitude of the amplitude detector calibration signal input to the signal processing circuit and the amplitude of the amplitude detector calibration signal acquired by the amplitude acquisition means. Correlation acquisition means for acquiring the correlation, and the ripple calculation means includes the correlation stored by the correlation acquisition means and the amplitude of the ripple measurement signal acquired by the amplitude acquisition means. Based on this, it is also possible to calculate a feature amount of ripples generated in the signal processing circuit.

  Further, in one aspect of the ripple characteristic correction circuit, the data indicating the correlation is the amplitude of the plurality of amplitude detector calibration signals input in a predetermined order by the amplitude detector calibration signal input means. And a difference amount between a plurality of amplitude detector calibration signals acquired by the amplitude acquisition unit, and the ripple calculation unit includes a plurality of the amplitude acquisition units acquired by the amplitude acquisition unit. A feature amount of ripple generated in the signal processing circuit may be calculated from an amplitude difference between ripple measurement signals based on an amount obtained by removing the difference amount indicated by the data indicating the correlation. .

  In another aspect of the ripple characteristic correction circuit, the data indicating the correlation includes the amplitude of the amplitude detector calibration signal input in a predetermined order by the amplitude detector calibration signal input means. And the amplitude of the amplitude detector calibration signal acquired by the amplitude acquisition means, and the ripple calculation means includes the amplitudes of the plurality of ripple measurement signals acquired by the amplitude acquisition means. From this, it is also possible to calculate a feature amount of a ripple generated in the signal processing circuit based on an amount obtained by removing the difference amount indicated by the data indicating the correlation.

  In the ripple characteristic correction circuit, the signal processing circuit includes a ripple generation circuit and an amplitude detector having the output of the ripple generation circuit as an input, and the input amplitude detector calibration signal and ripple The measurement signal is input to the ripple generation circuit, and the amplitude detector detects the amplitude of the amplitude detector calibration signal and the ripple measurement signal at the output of the ripple generation circuit. The amplitude characteristic of each signal is obtained by obtaining data indicating the detection result of the amplitude detected by the amplitude detector, and the ripple characteristic correction circuit supplies the amplitude detector calibration signal to the ripple generation circuit. The difference between the amplitude of the amplitude detector calibration signal acquired by the amplitude acquisition means and the amplitude at the input when input. Means for calculating a first phase difference amount, and when the amplitude detector calibration signal is input to the ripple generation circuit, the amplitude of the amplitude detector calibration signal output from the ripple generation circuit; When the amplitude detector calibration signal is input to the amplitude detector based on the second phase difference amount and the first phase difference amount, the amplitude acquisition means. Means for calculating a third phase difference amount, which is a difference amount between the amplitude of the amplitude detector calibration signal obtained by the above and the amplitude at the input, and the ripple measurement signal is input to the ripple generation circuit And a means for calculating a fourth phase difference which is a difference between the amplitude of the ripple measurement signal acquired by the amplitude acquisition unit and the amplitude at the input. From the fourth phase difference amount, The 3-phase different amounts based on the amount that was removed, to calculate the feature amount of the ripple generated by the ripple generating circuit, it is also possible.

  Further, in the ripple characteristic correction circuit, amplitude changing means for changing the amplitude of the signal processed in the signal processing circuit so as to cancel the ripple of the signal processing circuit indicated by the ripple characteristic amount calculated by the ripple calculating means. , May be further included.

  In the ripple characteristic correction circuit, the amplitude detector calibration signal input means may input the amplitude detector calibration signal having a common frequency to the signal processing circuit.

  The communication device according to the present invention is a communication device including a transmission circuit, wherein the amplitude detector calibration signal input means inputs a plurality of amplitude detector calibration signals having different amplitudes to the transmission circuit in a predetermined order. And a ripple measurement signal input means for inputting a plurality of ripple measurement signals having different frequencies to the transmission circuit in a predetermined order, the amplitude detector calibration signal output from the transmission circuit, and the ripple measurement. First amplitude acquisition means for acquiring the amplitude of the signal for use, and a feature amount of ripple indicating an amplitude change of the output signal due to a frequency change of the input signal in the transmission circuit based on the amplitude acquired by the first amplitude acquisition means And a transmission circuit ripple calculating means for calculating. In this way, the ripple of the transmission circuit can be detected without using a special measuring device, and therefore the ripple of the transmission circuit can be corrected at any time using the detection result. It becomes possible to further reduce the influence of.

  Further, in the communication apparatus, a transmission signal amplitude change for changing an amplitude of a transmission signal transmitted from the transmission circuit so as to cancel a ripple of the transmission circuit indicated by a ripple characteristic amount measured by the transmission circuit ripple calculating unit. Means may be further included.

  In the communication apparatus, the communication apparatus further includes a reception circuit, and the reception circuit receives the amplitude detector calibration signal and the ripple measurement signal output from the transmission circuit. Second amplitude acquisition means for measuring the amplitude of the amplitude detector calibration signal and the ripple measurement signal output from the reception circuit, the ripple of the transmission circuit calculated by the transmission circuit ripple calculation means, Receiving circuit ripple calculating means for calculating, based on the amplitude acquired by the second amplitude acquiring means, a ripple feature quantity indicating an amplitude change of the output signal due to a frequency change of the input signal in the receiving circuit. It is good. In this way, the ripples of the transmission circuit and the reception circuit can be detected without using a special measuring device, and therefore the ripples of the transmission circuit and the reception circuit can be corrected at any time using the detection result. Therefore, it is possible to further reduce the influence of ripples in the transmission circuit and the reception circuit.

  Further, in the communication apparatus, the received signal amplitude change for changing the amplitude of the received signal received by the receiving circuit so as to cancel the ripple of the receiving circuit indicated by the ripple characteristic amount measured by the receiving circuit ripple calculating unit. Means may be further included.

  A ripple characteristic correction method according to the present invention is a ripple characteristic correction method for correcting a ripple indicating an amplitude change of an output signal due to a frequency change of an input signal in a signal processing circuit. An amplitude detector calibration signal input step for inputting a plurality of amplitude detector calibration signals having different amplitudes in a predetermined order, and a plurality of ripple measurement signals having different frequencies respectively in a predetermined order to the signal processing circuit. It is acquired in the input step of ripple measurement signal input, the amplitude acquisition step of acquiring the amplitude detector calibration signal and the amplitude of the ripple measurement signal output from the signal processing circuit, respectively, and the amplitude acquisition step. A ripple calculating step for calculating a feature amount of a ripple generated in the signal processing circuit based on the amplitude; Characterized in that it comprises a.

  In the ripple characteristic correction method, an amplitude changing step of changing the amplitude of the signal processed in the signal processing circuit so as to cancel the ripple of the signal processing circuit indicated by the ripple feature amount calculated in the ripple calculating step. Further, it may be included.

  Embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the ripple characteristic correction circuit 10 according to the present exemplary embodiment includes an input A and an output A as inputs and outputs with the signal processing circuit 12. The signal processing circuit 12 includes a ripple generation circuit 14 and a detection circuit 16, and the output B of the ripple generation circuit 14 is configured to be an input of the detection circuit 16.

  The ripple in the baseband band means that the amplitude of the signal is slightly different depending on the frequency of the baseband signal. In other words, outputs when a plurality of signals input with the same amplitude and different frequencies pass through the circuit are output with different amplitudes. The amplitude deviation amount in this case is referred to as a ripple. The ripple is generally represented by a difference from an amplitude at a certain reference frequency. In the present embodiment, the ripple is generated in the ripple generation circuit 14. The ripple characteristic correction circuit 10 measures a ripple generated in the ripple generation circuit 14.

  The ripple generation circuit 14 generates a ripple when a signal passes through the inside. That is, it includes circuit elements that are prone to ripple. On the other hand, the detection circuit 16 which is an amplitude detector does not include a circuit element that generates a ripple, and the ripple hardly occurs even when a signal passes.

  Conversely, the amplitude of the output signal of the ripple generation circuit is composed of only circuit elements that change at least linearly with respect to the change of the amplitude of the input signal, while the amplitude of the output signal of the detection circuit 16 is the amplitude of the input signal. Circuit elements that change nonlinearly with respect to changes in

  Hereinafter, the operation of the ripple characteristic correction circuit 10 will be described.

First, the ripple characteristic correction circuit 10 sequentially inputs two amplitude detector calibration signals having different amplitudes from the input A to the ripple generation circuit 14. In this case, the amplitudes of the two amplitude detector calibration signals are A ₁₁ and A ₂₁ , respectively. The amplitude detector calibration signal is preferably a traveling wave having a constant frequency / amplitude. Here, it is assumed that the amplitude detector calibration signal is a traveling wave having a constant frequency / amplitude. The traveling wave is usually composed of electromagnetic waves (including light), but the same applies to, for example, sound waves and other vibration waves.

The amplitudes of the two amplitude detector calibration signals output from the output B of the ripple generation circuit 14 are A ₁₂ and A ₂₂ , respectively, and the difference in amplitude difference in the ripple generation circuit 14 (second phase difference). Is expressed by a function f ₁ (), these relationships are as shown in Equation (1).
A ₂₂ -A ₁₂ = f ₁ (A ₂₁ -A ₁₁ ) (1)

The two amplitude detector calibration signals output from the output B of the ripple generation circuit 14 are input to the detection circuit 16. The amplitudes of the two amplitude detector calibration signals output from the detection circuit 16 are respectively A ₁₃ and A _23, and the difference amount (third phase difference amount) of the amplitude difference in the detection circuit 16 is a function g ₁ ( ), These relationships are as shown in Equation (2).
_{A 23 -A 13 = g 1 (} A 22 -A 12) = g 1 (f 1 (A 21 -A 11)) ·· (2)

That is, Equation (2) shows the correlation between the amplitude difference of the output signal of the detection circuit 16 and the amplitude difference of the input signal to the ripple generation circuit 14. In other words, it represents the difference amount (first phase difference amount) between the amplitude difference of the output signal of the detection circuit 16 and the amplitude difference of the input signal to the ripple generation circuit 14. The function f ₁ is a linear change as described above, and can be obtained recursively with accuracy by measuring in advance the change in amplitude difference at the input / output of the ripple generation circuit 14. . That is, the second phase difference amount can be handled as a known one. On the other hand, the function g ₁ can also be calculated recursively by substituting the amplitude difference between the plurality of amplitude detector calibration signals and the function f ₁ obtained in advance into the equation (2). .

  In this way, the correlation between the amplitude difference of the output signal of the detection circuit 16 and the amplitude difference of the input signal to the ripple generation circuit 14 is a signal processing of a combination of a plurality of amplitude detector calibration signals each having a different amplitude difference. It can be calculated by inputting to the circuit 12. The correlation represents an output amplitude characteristic with respect to an input amplitude in the detection circuit 16, and the amplitude characteristic is acquired in advance before transmission of a ripple measurement signal, which will be described later, to calibrate the output of the ripple measurement signal. Used for.

Next, the ripple characteristic correction circuit 10 sequentially inputs two ripple measurement signals having different frequencies from the input A to the ripple generation circuit 14. In this case, the frequencies of the two ripple measurement signals are f ₁₁ and f ₂₁ , respectively. This ripple measurement signal is also preferably a traveling wave having a constant frequency and amplitude, similar to the amplitude detector calibration signal. In addition, it is desirable that the plurality of ripple measurement signals input to the ripple generation circuit 14 have the same amplitude. Here, the ripple measurement signal is a traveling wave having a constant frequency and amplitude, and a plurality of ripple measurement signals input to the ripple generation circuit 14 have the same amplitude. The traveling wave is usually composed of electromagnetic waves (including light), but the same applies to, for example, sound waves and other vibration waves.

Then, assuming that the amplitudes of the two ripple measurement signals output from the output B of the ripple generation circuit 14 are A ₁₄ and A ₂₄ , respectively, and the generation amount of the amplitude difference with respect to the frequency difference is represented by a function h (), these The relationship is as shown in Equation (3).
_{A 24 -A 14 = h (f} 21 -f 11) ·· (3)

Since the ripple generation circuit 14 is affected by the ripple, an amplitude difference is generated in the output signal due to the frequency difference of the input signal as shown in Expression (3). Then, since the amplitude difference has occurred, an amplitude difference is further generated in the detection circuit 16, and the amplitudes of the two amplitude detector calibration signals output from the detection circuit 16 are A ₁₅ and A ₂₅ , respectively. It is expressed as (4).
A ₂₅ −A ₁₅ = g ₁ (A ₂₄ −A ₁₄ ) = g ₁ (h (f ₂₁ −f ₁₁ )) (4)

For this reason, the function h can be calculated from the output of the ripple measurement signal from the detection circuit 16 as shown in Equation (5).
h (f ₂₁ −f ₁₁ ) = g ₁ ⁻¹ (A ₂₅ −A ₁₅ ) (5)

In this manner, the ripple characteristic correction circuit 10 is configured such that the frequency difference between the plurality of ripple measurement signals sequentially input to the signal processing circuit 12 and the plurality of ripple measurement signals output from the signal processing circuit 12. The function h, that is, the ripple in the signal processing circuit 12 can be calculated recursively by the amplitude difference between the two and the function g ₁ calculated in advance. That is, for example, if f ₁₁ is a reference frequency, the difference between the amplitude at the frequency f _{21 and} the amplitude at the reference frequency f ₁₁ is obtained, and this is calculated as a feature amount indicating the characteristics of the ripple generated in the signal processing circuit 12. Is done.

  The ripple can also be calculated as follows.

First, the ripple characteristic correction circuit 10 inputs an amplitude detector calibration signal having a certain amplitude from the input A to the ripple generation circuit 14. The amplitude of the amplitude detector calibration signal in this case the A _11. The amplitude detector calibration signal is also preferably a traveling wave having a constant frequency and amplitude.

Then, the amplitude of the amplitude detector calibration signals output from the output B of the ripple generating circuit 14 and A _12, in differences of amplitude in the ripple generating circuit 14 (second phase different amount) function f _{2 ()} If it represents, these relations will become like a formula (6).
A ₁₂ = f ₂ (A ₁₁ ) (6)

The amplitude detector calibration signal output from the output B of the ripple generation circuit 14 is input to the detection circuit 16. Then the amplitude of the amplitude detector calibration signals output from the detection circuit 16 and A _13, when the expressed by differences of the amplitude differences in the detection circuit 16 (phase 3 different amounts) function g _{2 (),} These relationships are as shown in Equation (7).
A ₁₃ = g ₂ (A ₁₂ ) = g ₂ (f ₂ (A ₁₁ )) (7)

That is, Expression (7) shows the correlation between the amplitude of the output signal of the detection circuit 16 and the amplitude of the input signal to the ripple generation circuit 14. In other words, it represents a difference amount (first phase difference amount) between the amplitude of the output signal of the detection circuit 16 and the amplitude of the input signal to the ripple generation circuit 14. The function f ₂ is a linear change as described above, and can be obtained recursively with high accuracy by measuring in advance the change in amplitude difference at the input / output of the ripple generation circuit 14. . On the other hand, the function g ₂ can also be calculated recursively by substituting the amplitude difference between the plurality of amplitude detector calibration signals and the function f ₂ obtained in advance into the equation (7). . In this way, the correlation between the amplitude of the output signal of the detection circuit 16 and the amplitude of the input signal to the ripple generation circuit 14 is input to the signal processing circuit 12 as a plurality of amplitude detector calibration signals having different amplitudes. Can be calculated.

Next, the ripple characteristic correction circuit 10 inputs the two ripple measurement signals having different frequencies from the input A to the ripple generation circuit 14 as described above. And Formula (4) is represented like the following formula | equation (8) and Formula (9).
A ₁₅ = g ₂ (A ₁₄ ) (8)
A ₂₅ = g ₂ (A ₂₄ ) (9)

Therefore, the function h can be calculated from the output of the ripple measurement signal from the detection circuit 16 as in Expression (10) from Expression (3), Expression (8), and Expression (9).
h (f ₂₁ −f ₁₁ ) = g ₂ ⁻¹ (A ₂₅ ) −g ₂ ⁻¹ (A ₁₅ ) (10)

Even in this way, the ripple characteristic correction circuit 10 is configured such that the frequency difference between the plurality of ripple measurement signals to the signal processing circuit 12, the amplitude of the plurality of ripple measurement signals output from the signal processing circuit 12, and With the function g ₂ calculated in advance, the function h, that is, the ripple in the signal processing circuit 12 can be calculated recursively. That is, for example, if f ₁₁ is a reference frequency, the difference between the amplitude at the frequency f _{21 and} the amplitude at the reference frequency f ₁₁ is obtained, and this is calculated as a feature amount indicating the characteristics of the ripple generated in the signal processing circuit 12. Is done.

  A signal passing through the signal processing circuit 12, for example, communication, is obtained by giving an amplitude difference to the signal input to the input A in advance using an amplitude control circuit (not shown) so as to cancel the ripple obtained as described above. It is possible to further reduce the influence of the ripple received by the ripple generation circuit 14 on the signal.

  Next, an embodiment when the above ripple measurement process is applied to a communication apparatus will be described.

  As shown in FIG. 2, the communication device 20 according to the present embodiment includes a control unit 22, a storage unit 24, a transmission unit 26, a switching unit 28, an antenna 30, a reception unit 32, and a detection unit 34. Device. Specifically, it may be a base station device or mobile station device used in mobile communication such as a mobile phone or a wireless LAN, or may be a wireless device used in amateur radio or the like. It can also be used in fixed wireless communication such as FWA (Fixed Wireless Access).

  The control unit 22 controls each unit of the communication device 20 and executes processing related to signal transmission / reception control and communication and data communication. The storage unit 24 operates as a work memory for the control unit 22. The storage unit 24 holds programs and parameters related to various processes performed by the control unit 22. Further, a program according to the present invention is also stored. The transmission unit 26 performs processing such as encoding / modulation processing and amplification processing for transmitting the transmission signal input from the control unit 22 and frequency conversion processing in the superheterodyne method, and transmits the transmission signal to the switching unit 28. Output. And the switching part 28 outputs the transmission signal output from the transmission part 26 to a radio area via the antenna 30 at the time of transmission. The time of transmission refers to a transmission time slot when, for example, a time division duplex method is adopted.

  When receiving a signal arriving at the antenna 30, the switching unit 28 outputs the received reception signal to the receiving unit 32. The receiving unit 32 performs processing such as demodulation / decoding processing and amplification processing for receiving the reception signal input from the switching unit 28, frequency conversion processing in the superheterodyne method, and the received signal is sent to the control unit 22 Output.

  The detection unit 34 receives a signal output from the transmission unit 26 to the switching unit 28. Specifically, the signal is received through a distribution unit such as a coupler. Then, the amplitude of the received signal is acquired and output to the control unit 22. That is, the detector 34 is an amplitude detector that measures the amplitude of the signal output from the transmitter 26. At this time, the amplitude may change due to the characteristics of the detection processing circuit in the detection unit 34. The amount of the change differs depending on the amplitude of the signal output from the transmission unit 26, while the amplitude of the detection unit 34 caused by the frequency change in the baseband band of the signal output from the transmission unit 26 is different. The change is minute, and the influence on the ripple measured in this embodiment can be ignored.

  FIG. 3 is a hardware configuration diagram for explaining an example of the above configuration of the communication device 20 in more detail. As shown in the figure, the communication device 20 includes a transmission baseband control unit 40 and a reception baseband control unit 82, which are included in the control unit 22. The transmission baseband control unit 40 and the reception baseband control unit 82 are connected to the storage unit 24 and to each other.

  The transmission baseband control unit 40 is connected to the transmission unit 26 via a D / A converter 44 included in the control unit 22. The D / A converter 44 inputs an analog transmission signal to the transmission unit 26 in accordance with an instruction from the transmission baseband control unit 40. The transmission signal is input to an amplifier 46 included in the transmission unit 26. The amplifier 46 further includes a primary IF-BPF 48, a multiplier 50, an amplifier 52, a secondary IF-BPF 54, a multiplier 56, an RF-BPF 58, The amplifier 60 and the distribution unit 62 are connected in this order, and the transmission signal is processed. D is an abbreviation for digital, A is an analog, BPF is a band pass filter, IF is an intermediate frequency, and RF is a radio frequency. The distribution unit 62 is connected to the switching unit 28 and the detection unit 34, and outputs a transmission signal to each. Here, DUP (duplexer) is used as the switching unit 28. However, for example, when the communication device 20 is simplex, SW (switch, SWitch) may be used.

  The receiving unit 32 is connected to the switching unit 28 by an amplifier 64, and a reception signal that is a radio signal received by the antenna 30 is input from the switching unit 28. Further, the RF-BPF 66, the multiplier 68, the amplifier 70, the primary IF-BPF 72, the multiplier 74, the amplifier 76, and the secondary IF-BPF 78 are connected in this order, and the received signal is processed. Then, the received signal is input to the A / D converter 80 included in the control unit 22, and the received signal is digitized. Information indicating the reception signal is output to the reception baseband control unit 82.

  Note that the communication device 20 employs a conventionally known double superheterodyne method, and the transmission unit 26 and the reception unit 32 transmit and receive signals while converting the communication signal into a two-stage intermediate frequency. The frequency conversion processing is performed by the multiplier 50, the multiplier 56, the multiplier 68, and the multiplier 74. The frequency conversion is performed by multiplying the signals from the local transmitter 90 and the local transmitter 92.

  The detection unit 34 receives a signal output from the distribution unit 62 and performs detection processing in the detection unit 34. Specifically, for example, the detection unit 34 is installed to perform automatic gain control for reflecting the transmission power of the transmission signal in the distribution unit 62 in the transmission power in the transmission baseband control unit 40, and the detection unit As the detection process in 34, a process of acquiring the amplitude of the signal output from the distribution unit 62 is performed. Then, a signal indicating the amplitude is output to the control unit 22, and the control unit 22 converts the signal into a digital signal in the A / D converter 96 and outputs the digital signal to the transmission baseband control unit 40. In this way, the transmission baseband control unit 40 acquires the transmission signal distribution unit 62 amplitude, that is, transmission power.

  Next, the ripple measurement process in the communication device 20 will be described.

  First, processing for measuring the ripple of the transmission unit 26 will be described. First, in the control unit 22, the transmission baseband control unit 40 instructs the D / A converter 44 to transmit an amplitude detector calibration signal. Then, the D / A converter 44 sequentially generates amplitude detector calibration signals and outputs them to the transmitter 26. At this time, a plurality of amplitude detector calibration signals are transmitted, and the respective transmission powers are made different. The amplitude detector calibration signal is preferably a sine wave (unmodulated carrier wave). That is, it is desirable that the traveling wave has a constant frequency.

  The amplitude detector calibration signal is amplified and frequency-converted by the transmission unit 26 by the same process as the communication signal, and is output to the detection unit 34 via the distribution unit 62. The detector 34 acquires the amplitude of the amplitude detector calibration signal that is input, and the A / D converter 96 converts the signal indicating the amplitude into a digital signal. The detector 34 then outputs a signal indicating the amplitude of the amplitude detector calibration signal obtained in this way to the controller 22.

  As described above, the control unit 22 can acquire the amplitude at the time of transmission of the amplitude detector calibration signal transmitted by itself and the amplitude of the amplitude detector calibration signal output from the detection unit 34. Then, by obtaining a change in amplitude for a plurality of amplitude detector calibration signals, the amplitude difference between the amplitude detector calibration signals transmitted by itself and the amplitude detector calibration output from the detector 34 are transmitted. The above-mentioned correlation between the amplitude difference between the signals for use and the above correlation or the amplitude at the time of transmission of the amplitude detector calibration signal transmitted by itself and the amplitude of the amplitude detector calibration signal output from the detector 34 To get.

  Next, in the control unit 22, the transmission baseband control unit 40 instructs the D / A converter 44 to transmit a ripple measurement signal. The D / A converter 44 generates a ripple measurement signal and outputs it to the transmission unit 26. At this time, a plurality of ripple measurement signals are sequentially transmitted, and the respective transmission frequencies are made different. The ripple measurement signal is also preferably a sine wave (unmodulated carrier wave). That is, it is desirable that the traveling wave has a constant frequency.

  The ripple measurement signal is amplified and frequency-converted by the transmission unit 26 by the same processing as the communication signal, and is output to the detection unit 34 via the distribution unit 62. The detector 34 acquires the amplitude of the input ripple measurement signal, and the A / D converter 96 converts the signal indicating the amplitude into a digital signal. Then, the detector 34 outputs a signal indicating the amplitude of the ripple measurement signal obtained in this manner to the controller 22.

  As described above, the control unit 22 can acquire the amplitude of the ripple measurement signal transmitted by itself and the amplitude of the ripple measurement signal output from the detection unit 34. Then, by obtaining a change in amplitude for a plurality of ripple measurement signals, the difference in frequency between the ripple measurement signals transmitted by itself and the amplitude or amplitude of the ripple measurement signal output from the detector 34 is detected. The ripple of the transmitter 26 can be calculated from the difference and the correlation.

  Actually, the circuit elements that contribute to the generation of ripples in the transmitter 26 in the baseband frequency band are the primary IF-BPF 48 and the secondary IF-BPF 54, and most of the calculated ripples are in these parts. It has occurred. The same applies to the receiving unit 32 described below, and most of the ripples generated in the receiving unit 32 are generated in the primary IF-BPF 72 and the secondary IF-BPF 78.

  Next, processing for measuring the ripple of the receiving unit 32 will be described. In order to calculate the ripple of the reception unit 32, the ripple of the transmission unit 26 calculated by the above processing is required. In the control unit 22, the transmission baseband control unit 40 instructs the D / A converter 44 to transmit a ripple measurement signal. The D / A converter 44 generates a ripple measurement signal and outputs it to the transmission unit 26. At this time, a plurality of ripple measurement signals are sequentially transmitted, and the respective transmission frequencies are made different. The ripple measurement signal is also preferably a sine wave (unmodulated carrier wave). That is, it is desirable that the traveling wave has a constant frequency.

The ripple measurement signal is amplified and frequency-converted by the transmission unit 26 by the same process as the communication signal, and is output to the reception unit 32 via the switch 28. At this time, the switch 28 performs processing for passing the signal from the transmission unit 26 to the reception unit 32. This process may be, for example, a process of detecting a leakage high frequency from the transmission unit 26 in the amplifier 64. In the receiving unit 32, the input ripple measurement signal is amplified and frequency-converted by the same processing as the communication signal, and is output to the A / D converter 80 of the control unit 22. The A / D converter 80 digitizes the reception signal and outputs information indicating the amplitude of the reception signal to the reception baseband control unit 82. In this manner, the control unit 22 can acquire the amplitude of the ripple measurement signal transmitted by itself and the amplitude of the ripple measurement signal output from the reception unit 32. Then, by obtaining a change in amplitude for a plurality of ripple measurement signals, the frequency difference during transmission between the ripple measurement signals transmitted by itself, and the amplitude difference between the ripple measurement signals output from the receiving unit 32, and The ripple of the receiver 32 can be calculated from the calculated ripple of the transmitter 26. At this time, the frequency difference of the ripple measurement signal input to the transmission unit 26 by the control unit 22 is δf, the amplitude difference of the ripple measurement signal output from the reception unit 32 is δA, and the ripple of the transmission unit 26 is h _S ( Assuming that δf), the ripple h _R (δf) of the receiving unit 32 can be expressed by the following equation (11).
h _R (δf) = δA−h _S (δf) (11)

  As described above, the control unit 22 can acquire the ripples of the transmission unit 26 and the reception unit 32, respectively. Then, by storing the ripple acquired in this way in the storage unit 24, for example, the amplitude of the communication signal transmitted from the transmission unit 26 is reduced so that the influence of the ripple is eliminated in the output from the transmission unit 26. If it is changed in advance according to the stored ripple, a trimmer capacitor for correcting the ripple component in advance is installed at the input stage of the circuit, and the ripple of the circuit is reduced when a product including the circuit is shipped. By measuring the capacitance of the trimmer capacitor by measuring and minimizing the ripple as a product, the influence of the ripple in the transmission unit 26 on the transmission power of the communication signal transmitted from the antenna 30 is further reduced. can do. That is, even after the operation of the communication device 20 is started, the ripple can be measured at any time as long as the ripple measurement signal can be passed through the circuit, and the amplitude of the transmission signal can be corrected according to the stored ripple. Therefore, the ripple can be corrected in response to a slight change in the ripple due to the external environment such as temperature and humidity. Further, for example, the amplitude of the output signal from the switching unit 28 is changed in advance according to the stored ripple so that the influence of the ripple on the output from the receiving unit 32 is eliminated. By doing so, it is possible to further reduce the influence of ripples on the output from the receiving unit 32.

  Next, the processing described above will be described more specifically with reference to the processing flowchart of the control unit 22.

First, the pre-calibration process will be described. FIG. 4 is a process flow diagram of the pre-calibration process in the control unit 22. First, the control unit 22 secures storage areas for the variable P ₀ , the variable N, and the output change counter A, and the reference output serving as a reference for the amplitude of the amplitude detector calibration signal and the amplitude detector calibration signal having different amplitudes. The output change dynamic range, which is the width of the amplitude change when outputting, and 0 are substituted (S100). Then, an amplitude detector calibration signal is input to the transmitter 26 as an output of P ₀ + A (S102). Then, the amplitude detector calibration signal is detected by the detection unit 34, and the reception voltage having the amplitude is input, so the reception voltage is stored in the storage unit 24. At this time, it is stored in association with P ₀ + A, which is the output when input to the transmitter 26 (S104). Then, A is increased by 0.1 (S106). The processing from S102 to S106 is repeated until A becomes N (S108). When A = N, the correlation between the output when the signal is input to the transmission unit 26 and the reception voltage is obtained, and the storage unit 24 stores the correlation. Store (S110). The correlation may be a regression equation or a correspondence table between output amplitude and input amplitude. Further, it may be a correlation between an output difference between a plurality of amplitude detector calibration signals and a received voltage difference.

Next, processing for calculating the ripple of the transmission unit 26 will be described. FIG. 5 is a process flow diagram of the process of calculating the ripple of the transmission unit 26 in the control unit 22. First, the control unit 22 secures storage areas for the variable F _bc , the variable F _w , the variable N, and the sweep counter A, and the center frequency, the baseband frequency bandwidth, The bandwidth sweep step and 0 are substituted (S150). Then, a ripple measurement signal is input to the transmission unit 26 at a frequency of F _bc − (F _w / 2) + (A × F _w / N) (S152). Then, the ripple measurement signal is detected by the detection unit 34 and the reception voltage having the amplitude is input, so that the reception voltage is stored in the storage unit 24. At this time, it is stored in association with F _bc − (F _w / 2) + (A × F _w / N), which is the frequency when input to the transmission unit 26 (S154). Then, A is increased by 1 (S156). The processing from S152 to S156 is repeated until A becomes N (S158), and when A = N, the difference between the frequency at the time of input to the transmission unit 26 and the center frequency F _bc and the difference in received voltage Based on the correlation stored in the pre-calibration process, the ripple of the transmission unit 26 is calculated and stored in the storage unit 24 (S160). The stored ripple may be a regression equation or a correspondence table between the difference between the output frequency and the center frequency and the input amplitude difference after calibration.

Next, processing for calculating the ripple of the receiving unit 32 will be described. FIG. 6 is a process flow diagram of the process of calculating the ripple of the reception unit 32 in the control unit 22. First, the control unit 22 secures storage areas for the variable F _bc , the variable F _w , the variable N, and the sweep counter A, and the center frequency, the baseband frequency bandwidth, A bandwidth sweep step and 0 are substituted (S200). Then, a ripple measurement signal is input to the transmission unit 26 at a frequency of F _bc − (F _w / 2) + (A × F _w / N) (S202). Then, the ripple measurement signal is received by the receiving unit 32, and the reception voltage that is the amplitude of the output from the receiving unit 32 is input, so the received voltage is stored in the storage unit 24. At this time, it is stored in association with F _bc − (F _w / 2) + (A × F _w / N), which is the frequency when input to the transmitter 26 (S204). Then, A is increased by 1 (S206). The processes from S202 to S206 are repeated until A becomes N (S208). When A = N, the difference between the frequency when the signal is input to the transmitter 26 and the center frequency F _bc and the difference between the received voltages Based on the ripple of the transmission unit 26 stored in the processing of calculating the ripple of the transmission unit 26, the ripple of the reception unit 32 is calculated and stored in the storage unit 24 (S210). The stored ripple may be a regression equation, or may be a correspondence table between the difference between the center frequency of the output frequency and the difference in input amplitude obtained by subtracting the ripple of the transmission unit 26. Good.

It is a block diagram of the ripple characteristic correction circuit which concerns on embodiment of this invention. It is a functional block diagram of the communication apparatus which concerns on embodiment of this invention. It is a hardware block diagram of the communication apparatus which concerns on embodiment of this invention. It is a processing flow figure of the communication apparatus which concerns on embodiment of this invention. It is a processing flow figure of the communication apparatus which concerns on embodiment of this invention. It is a processing flow figure of the communication apparatus which concerns on embodiment of this invention.

Explanation of symbols

  10 ripple characteristic correction circuit, 12 signal processing circuit, 14 ripple generation circuit, 16 detection circuit, 20 communication device, 22 control unit, 24 storage unit, 26 transmission unit, 28 switching unit, 30 antenna, 32 reception unit, 34 detection unit , 40 Transmission baseband control unit, 44 D / A converter, 46, 52, 60, 64, 70, 76 Amplifier, 48, 72 Primary IF-BPF, 50, 56, 68, 74 Multiplier, 54, 78 2 Next IF-BPF, 58, 66 RF-BPF, 62 Distribution unit, 80, 96 A / D converter, 82 Reception baseband control unit, 90, 92 Local transmitter.

Claims (4)

A ripple characteristic correction circuit for correcting the ripple generating circuit to which a signal is input, an amplitude detector for detecting the amplitude of the signal output from the ripple generating circuit, the Brighter ripple put to a signal processing circuit including a And
Means for obtaining a known first input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the ripple generation circuit;
Type different amplitude detector calibration signal of said ripple generator Niso respectively amplitude, by obtaining the amplitude of the amplitude detector calibration signal detected by the amplitude detector, respectively, wherein Means for obtaining a second input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the signal processing circuit ;
Enter multiple ripple measurement signals having the different ripple generating circuit Niso Re respective frequency, by obtaining the amplitude of the ripple measurement signal detected by the amplitude detector, respectively, in the signal processing circuit Means for obtaining a third input / output characteristic indicating a correlation between the input frequency and the output amplitude ;
Means for obtaining a fourth input / output characteristic indicating a correlation between an input frequency and an output amplitude in the ripple generation circuit based on the first to third input / output characteristics;
A ripple calculating means for calculating a feature amount of a ripple generated in the ripple generating circuit based on the fourth input / output characteristic ;
Amplitude changing means for changing the amplitude of the signal input to the signal processing circuit so as to cancel the ripple of the ripple generating circuit indicated by the ripple feature amount calculated by the ripple calculating means;
A ripple characteristic correction circuit comprising: The ripple characteristic correction circuit according to claim 1 ,
The plurality of amplitude detector calibration signals have a common frequency ,
A ripple characteristic correction circuit characterized by that. A communication device including a signal processing circuit including a transmission circuit to which a signal is input and an amplitude detector for detecting the amplitude of the signal output from the transmission circuit ,
Means for obtaining a known first input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the transmission circuit;
Wherein by entering the transmission circuit Niso respectively a plurality of amplitude detectors calibration signals with different amplitudes, by obtaining the amplitude of the amplitude detector calibration signal detected by the amplitude detector, respectively, the signal Means for obtaining a second input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the processing circuit ;
Enter multiple ripple measurement signals having the different transmission circuit Niso Re respective frequency, by obtaining the amplitude of the ripple measurement signal detected by the amplitude detector, respectively, the input of the signal processing circuit Means for obtaining a third input / output characteristic indicating a correlation between the frequency and the output amplitude ;
Means for obtaining a fourth input / output characteristic indicating a correlation between an input frequency and an output amplitude in the transmission circuit based on the first to third input / output characteristics;
A transmission circuit ripple calculating means for calculating a characteristic amount of a ripple generated in the transmission circuit based on the fourth input / output characteristic ;
Amplitude changing means for changing the amplitude of the transmission signal input to the transmission circuit so as to cancel the ripple of the transmission circuit indicated by the ripple feature amount calculated by the transmission circuit ripple calculation means;
A communication device comprising: A ripple characteristic correction method for correcting a ripple generating circuit to which a signal is input, an amplitude detector for detecting the amplitude of the signal output from the ripple generating circuit, the Brighter ripple put to a signal processing circuit including a And
Obtaining a known first input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the ripple generation circuit;
Type different amplitude detector calibration signal of said ripple generator Niso respectively amplitude, by obtaining the amplitude of the amplitude detector calibration signal detected by the amplitude detector, respectively, wherein Obtaining a second input / output characteristic indicating a correlation between an input amplitude and an output amplitude in the signal processing circuit ;
Enter multiple ripple measurement signals having the different ripple generating circuit Niso Re respective frequency, by obtaining the amplitude of the ripple measurement signal detected by the amplitude detector, respectively, in the signal processing circuit Obtaining a third input / output characteristic indicating a correlation between the input frequency and the output amplitude ;
Obtaining a fourth input / output characteristic indicating a correlation between an input frequency and an output amplitude in the ripple generation circuit based on the first to third input / output characteristics;
A ripple calculating step for calculating a feature amount of a ripple generated in the ripple generating circuit based on the fourth input / output characteristic ;
An amplitude changing step of changing the amplitude of the signal input to the signal processing circuit so as to cancel the ripple of the ripple generating circuit indicated by the ripple feature amount calculated by the ripple calculating unit;
A method for correcting ripple characteristics, comprising:

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