JP4806621B2 - Detection device, analog modulation circuit, and test device - Google Patents

Description

  The present invention relates to a detection device, an analog modulation circuit, and a test device. In particular, the present invention relates to a detection device, an analog modulation circuit, and a test device that detect skew of first and second analog signals supplied in parallel from a signal generation device to a signal processing device.

  As an example, a test apparatus that tests a receiving apparatus includes a signal generator and a quadrature modulator. The signal generation device generates a two-channel transmission signal to be transmitted to the reception device. The quadrature modulator generates a modulated signal obtained by quadrature modulating a 2-channel transmission signal with a local signal. Then, the test apparatus supplies the modulation signal generated by the quadrature modulator as a test signal to the reception apparatus, and tests the reception apparatus.

  Here, the test apparatus adjusts the skew between the channels of the signal generator by calibration so that the transmission signals of the two channels generated from the signal generator reach the quadrature modulator without any phase shift. As an example, the test apparatus analyzed the delay difference between the first channel and the second channel from the signal generator to the quadrature modulator by using, for example, a network analyzer, and adjusted the skew according to the analysis result. .

  In addition, since the presence of a prior art document is not recognized at this time, the description regarding a prior art document is abbreviate | omitted.

  However, the method of adjusting the skew of the two-channel transmission signal generated from the signal generator using a network analyzer is time-consuming and requires a large apparatus configuration. Therefore, this method was expensive.

  Accordingly, an object of the present invention is to provide a detection device, an analog modulation circuit, and a test device that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.

In order to solve the above-described problem, in the first embodiment of the present invention, there is provided a detection device for detecting a skew of first and second analog signals supplied in parallel from a signal generation device to a signal processing device, A signal control unit that causes the signal generator to output a first analog signal of a sine wave signal and a second analog signal of a cosine wave signal having substantially the same period as the first analog signal, and the signal generator outputs A multiplication unit that multiplies the first analog signal and the second analog signal, an integration unit that outputs an integration signal obtained by integrating the multiplication result in the multiplication unit, and an absolute value of the level of the integration signal is minimized. , and a skew adjustment unit for adjusting the phase of the first analog signal and second analog signal signal generating device outputs, the signal control unit, a first of the signal generator changes the phase difference sequentially The skew adjustment unit measures the level of the integrated signal for each phase difference and outputs the analog signal and the second analog signal based on the differential value obtained by differentiating the level of the integrated signal with the phase difference. Provided is a detection device that adjusts the phases of a first analog signal and a second analog signal .

In the second aspect of the present invention, an analog modulation circuit that modulates and outputs a generated transmission signal, a signal generator that generates an I signal and a Q signal of the transmission signal, and a transmission signal received from the signal generator A signal processing device that modulates and outputs the transmission signal, the signal processing device multiplying the I signal received via the first input terminal by a predetermined local signal, and a local signal A shift unit that shifts the phase by approximately 90 degrees, a Q-side multiplier that multiplies the Q signal received via the second input terminal by a local signal output from the shift unit, and a signal that is output from the I-side multiplier An output unit that adds and outputs the signal output from the Q-side multiplier, a detection device that detects a skew between the I signal received by the first input terminal and the Q signal received by the second input terminal; And the detection device is A signal generator, a signal control unit for outputting a second analog signal of the cosine wave signal having a first analog signal and the first analog signal is substantially the same period of the sine wave signal, from the first input terminal A multiplier that branches to receive the first analog signal, branches from the second input terminal to receive the second analog signal, and multiplies the first analog signal and the second analog signal; An integration unit that outputs an integration signal obtained by integrating the multiplication results , and adjusts the phases of the first analog signal and the second analog signal output by the signal generator so that the absolute value of the level of the integration signal is minimized. look including a skew adjusting unit, the signal control unit, the signal generator, to output the first analog signal and second analog signal a phase difference sequentially changes, the skew adjusting unit, the product for each phase The level of the signal is measured, the level of the integrated signal based on the differential value obtained by differentiating the phase difference, providing an analog modulation circuit for adjusting the phase of the first analog signal and second analog signal signal generating device outputs To do.

In the third embodiment of the present invention, there is provided a test apparatus for testing a receiving circuit under test, which modulates a generated transmission signal and outputs it to the receiving circuit under test, and a signal output from the analog modulation circuit The analog modulation circuit receives a transmission signal from the signal generator, a signal generator that generates an I signal and a Q signal of the transmission signal, and a determination unit that determines a signal output from the receiving circuit under test according to A signal processing device that modulates and outputs a transmission signal, the signal processing device including an I-side multiplier that multiplies the I signal received via the first input terminal by a predetermined local signal, and a local signal A shift unit that shifts the phase by approximately 90 degrees, a Q-side multiplier that multiplies the Q signal received via the second input terminal by a local signal output from the shift unit, and a signal that is output from the I-side multiplier Q side An output unit that adds and outputs a signal output from the arithmetic unit; and a detection device that detects a skew between the I signal received by the first input terminal and the Q signal received by the second input terminal. , the detection device, the signal generator, a signal control unit for outputting a second analog signal of the cosine wave signal having a first analog signal and the first analog signal is substantially the same period of the sine wave signal, the A multiplier that branches from the first input terminal and receives the first analog signal, branches from the second input terminal and receives the second analog signal, and multiplies the first analog signal and the second analog signal An integration unit that outputs an integration signal obtained by integrating the multiplication results of the multiplication unit, and a first analog signal and a second analog signal output by the signal generator so that the absolute value of the level of the integration signal is minimized. Place of Look including a skew adjustment unit for adjusting the signal control unit, the signal generator, to output the first analog signal and second analog signal a phase difference sequentially changes, the skew adjusting unit, each phase difference A test apparatus that measures the level of the integrated signal and adjusts the phases of the first analog signal and the second analog signal output from the signal generator based on a differential value obtained by differentiating the level of the integrated signal by the phase difference. provide.

  The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

  Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention according to the scope of claims, and all combinations of features described in the embodiments are included. It is not necessarily essential for the solution of the invention.

  FIG. 1 shows a configuration of a test apparatus 10 according to the present embodiment, together with a receiving circuit 100 under test. The test apparatus 10 includes a waveform data generation unit 12, an analog modulation circuit 20, and a determination unit 14, and tests the receiving circuit under test 100.

  The waveform data generator 12 generates waveform data of a first analog signal and a second analog signal, which are 2-channel transmission signals transmitted to the receiving circuit under test 100. The analog modulation circuit 20 generates a first analog signal and a second analog signal according to the waveform data generated by the waveform data generator 12. Then, the analog modulation circuit 20 modulates the first and second analog signals that are the generated transmission signals and outputs them to the receiving circuit under test 100. For example, the analog modulation circuit 20 may output a modulated signal obtained by orthogonally modulating the first and second analog signals with a local signal to the receiving circuit under test 100.

  The determination unit 14 determines the signal output from the test receiver circuit 100 according to the signal output from the analog modulation circuit 20. For example, the determination unit 14 compares the output signal output from the test receiver circuit 100 in accordance with the modulation signal supplied from the analog modulation circuit 20 with the expected value signal, and determines whether the test receiver circuit 100 is good or bad. May be determined.

  FIG. 2 shows a configuration of the analog modulation circuit 20 according to the present embodiment. The analog modulation circuit 20 includes a signal generation device 30 and a signal processing device 40. The signal generator 30 generates a first analog signal and a second analog signal of the transmission signal. The signal processing device 40 receives the first analog signal and the second analog signal that are transmission signals from the signal generation device 30, modulates the transmission signal, and outputs the modulated signal. As an example, the signal processing device 40 outputs a modulated signal obtained by orthogonally modulating the first analog signal and the second analog signal with a local signal.

  The signal processing device 40 includes a first input terminal 42, a second input terminal 44, an operation circuit 50, and a detection device 70. The first input terminal 42 receives the first analog signal output from the signal generator 30. The second input terminal 44 receives the second analog signal output from the signal generator 30.

  The operation circuit 50 receives the first analog signal from the first input terminal 42 and the second analog signal from the second input terminal 44, and operates according to the first analog signal and the second analog signal. For example, the operation circuit 50 modulates the first analog signal received by the first input terminal 42 and the second analog signal received by the second input terminal 44 with a predetermined local signal, and receives the circuit under test. 100 may be output.

  For example, the operation circuit 50 may include a local signal generator 52, an I-side multiplier 54, a shift unit 56, a Q-side multiplier 58, and an output unit 60. The local signal generator 52 generates a predetermined local signal having a predetermined frequency. The I-side multiplier 54 multiplies the first analog signal received via the first input terminal 42 by a predetermined local signal generated from the local signal generator 52.

  The shift unit 56 shifts the phase of the local signal generated from the local signal generator 52 by approximately 90 degrees. The Q-side multiplier 58 multiplies the second analog signal received via the second input terminal 44 by the local signal output from the shift unit 56. The output unit 60 includes, for example, an adder, adds the signal output from the I-side multiplier 54 and the signal output from the Q-side multiplier 58 and outputs the result. According to such an operation circuit 50, the first analog signal and the second analog signal can be quadrature-modulated with a predetermined local signal.

  For example, during calibration, the detection device 70 detects a skew between the first analog signal received by the first input terminal 42 and the second analog signal received by the second input terminal 44. That is, the detection device 70 detects the skew of the first and second analog signals supplied in parallel from the signal generation device 30 to the signal processing device 40. In addition to this, the detection device 70 adjusts the phases of the first analog signal and the second analog signal output from the signal generation device 30 so that the skew becomes substantially zero according to the detected skew. Good. The detection device 70 may be provided inside the signal processing device 40 or may be provided outside the signal processing device 40. In the detection device 70, the input of the first and second analog signals may be cut by a switch at a time other than calibration.

  The detection device 70 includes a signal control unit 72, a multiplication unit 74, a detection unit 76, and a skew adjustment unit 78. The signal control unit 72 causes the signal generator 30 to output a first analog signal and a second analog signal having substantially the same period. For example, the signal control unit 72 outputs a sine wave signal as the first analog signal and also has a cosine wave signal (that is, the phase of the sine wave signal) having substantially the same phase as the sine wave signal as the second analog signal. ) May be outputted.

  The multiplier 74 multiplies the first analog signal and the second analog signal. For example, the multiplier 74 may multiply the sine wave signal output from the signal generator 30 as the first analog signal and the cosine wave signal output from the signal generator 30 as the second analog signal. . For example, the multiplication unit 74 branches from the first input terminal 42 to receive a first analog signal (for example, a sine wave signal) and branches from the second input terminal 44 to branch to a second analog signal (for example, cosine). Wave signal) and the first analog signal output from the signal generator 30 may be multiplied by the second analog signal.

  The detection unit 76 outputs a signal having a level corresponding to the skew value of the first and second analog signals (for example, a sine wave signal and a cosine wave signal) based on the multiplication result in the multiplication unit 74. The detection unit 76 may include an integration unit 82 as an example. The integration unit 82 outputs an integration signal obtained by integrating the multiplication result in the multiplication unit 74 as a signal having a level corresponding to the skew value.

  The skew adjustment unit 78 is based on a signal (for example, an integration signal) having a level corresponding to the skew value output from the detection unit 76, and the phases of the first analog signal and the second analog signal output from the signal generator 30. Adjust. As an example, the skew adjustment unit 78 reduces the skew of the first analog signal and the second analog signal (for example, the skew of the first analog signal and the second analog signal becomes substantially zero). The phases of the first analog signal and the second analog signal output from the signal generator 30 may be adjusted.

  As an example, the skew adjustment unit 78 adjusts the delay amount of the transmission line that transmits the first and second analog signals between the signal generation device 30 and the signal processing device 40, so that the first analog signal and The phase of the second analog signal may be adjusted. Further, as an example, the skew adjustment unit 78 delays the operation clock of the circuit that generates the first analog signal or the operation clock of the circuit that generates the second analog signal in the signal generator 30, thereby The phases of the analog signal and the second analog signal may be adjusted.

  Then, after the calibration is completed, the signal generator 30 outputs the first and second analog signals corresponding to the waveform data output from the waveform data generator 12 with the phase adjusted by the skew adjuster 78. To do. Thereby, the signal generating device 30 can supply the first analog signal and the second analog signal with small skew to the signal processing device 40. Therefore, the signal processing device 40 can supply the signal under test 100 with a modulated signal obtained by modulating the first analog signal and the second analog signal with small skew with the local signal.

  According to such an analog modulation circuit 20, the skew of the first analog signal and the second analog signal supplied in parallel from the signal generating device 30 to the signal processing device 40 can be obtained without using a network analyzer or the like. Can be adjusted. Thereby, according to the analog modulation circuit 20, the skew of the first analog signal and the second analog signal can be adjusted with a simple configuration. According to the test apparatus 10 including such an analog modulation circuit 20, the receiving circuit 100 under test can be tested with high accuracy at low cost.

  FIG. 3A illustrates an example of a first analog signal (sine wave signal), and FIG. 3B illustrates an example of a second analog signal (cosine wave signal). FIG. 3C illustrates a multiplication result when there is a skew between the first analog signal and the second analog signal, and FIG. 3D illustrates the first analog signal and the second analog signal. An example of a multiplication result when there is no skew between them is shown.

  Here, it is assumed that the signal generation device 30 outputs a sine wave signal as the first analog signal and outputs a cosine wave signal as the second analog signal in accordance with control by the signal control unit 72. In this case, assuming that the phase difference caused by the skew of the sine wave signal and the cosine wave signal input to the signal processing device 40 is θ, the multiplication result Vr by the multiplication unit 74 is expressed by the following equation (1).

  In this case, the integrating unit 82 outputs an integrated signal obtained by integrating the expression (1). That is, the integration unit 82 outputs an integration signal Vo as represented by the following formula (2) obtained by averaging the formula (1).

  Referring to Equation (2), the integration signal Vo simply decreases with an increase in the phase difference θ caused by the skew, and becomes 0 when the phase difference θ caused by the skew is zero. That is, the phase difference θ caused by the skew decreases as the level of the integration signal Vo increases, and becomes 0 when the integration signal Vo is 0.

  From this, as an example, the skew adjustment unit 78 outputs the integrated signal output from the detection unit 76 when the sine wave signal is output as the first analog signal and the cosine wave signal is output as the second analog signal. You may adjust the phase of the 1st analog signal and the 2nd analog signal which the signal generator 30 outputs so that the absolute value of the level of Vo may become the minimum. As a result, the skew adjustment unit 78 can reduce the skew between the first analog signal and the second analog signal to substantially zero.

  FIG. 4 shows a first example (rectangular wave signal) of the first and second analog signals output from the signal generator 30 according to the present embodiment in accordance with the control of the signal control unit 72. FIG. 5 shows a second example (triangular wave signal) of the first and second analog signals output from the signal generator 30 of the present embodiment in accordance with the control of the signal control unit 72.

  The signal control unit 72 is not limited to the sine wave signal and the cosine wave signal, and may output the first analog signal and the second analog signal of the periodic signal having substantially the same waveform from the signal generator 30. As an example, the signal control unit 72 may output a rectangular wave signal having a phase difference of about 90 degrees in substantially the same cycle as shown in FIG. 4 as the first analog signal and the second analog signal. Further, as an example, the signal control unit 72 outputs substantially the same triangular wave signal having a phase difference of 90 degrees with substantially the same period as shown in FIG. 5 as the first analog signal and the second analog signal. Good.

  Further, as an example, the signal control unit 72 may set the phase shift amount between the first analog signal and the second analog signal having waveforms with substantially the same period as a phase difference other than 90 degrees. For example, the signal control unit 72 may set the phase shift amount between the first analog signal and the second analog signal to 0 degrees or 180 degrees.

  Then, as an example, the skew adjustment unit 78 is configured so that the value corresponding to the skew output from the detection unit 76 becomes a value corresponding to the phase shift amount set by the signal control unit 72. The phase of the output first analog signal and second analog signal may be adjusted. As an example, the skew adjustment unit 78 integrates the multiplication result of the multiplication unit 74 so that the value according to the phase shift amount set by the signal control unit 72 (for example, the multiplication result of the multiplication unit 74 is calculated). The phases of the first analog signal and the second analog signal output from the signal generator 30 may be adjusted so that the integrated value becomes the maximum value, the minimum value, or 0. Since the waveform generation is simple, does not include high frequency components, and the skew is 0 when the average value of the multiplication results is 0, the control for reducing the skew is simple. It is preferable to output the sine wave signal and the cosine wave signal from the signal generator 30 as the first and second analog signals.

  FIG. 6 shows a processing flow of the analog modulation circuit 20 according to the first modification of the present embodiment. The analog modulation circuit 20 according to the present modification employs substantially the same configuration and function as the analog modulation circuit 20 shown in FIG.

  First, the skew adjustment unit 78 stops the first and second analog signals output from the signal generator 30, that is, sets the first and second analog signals to 0 and outputs them from the detection unit 76. The value (offset value) of the signal to be detected is detected (S1001). Then, the skew adjustment unit 78 stores the detected offset value.

  Next, the signal control unit 72 outputs a sine wave signal as the first analog signal and also outputs a cosine wave signal as the second analog signal, and causes the detection unit 76 to output the first analog signal and the second analog signal. A value corresponding to the skew between the analog signals is detected. Instead of this, the signal control unit 72 may output signals other than the sine wave signal and the cosine wave signal as the first and second analog signals. Then, the skew adjustment unit 78 subtracts the offset value detected in step S1001 from the signal detected by the detection unit 76, and the first analog signal and the second analog signal output from the signal generator 30 based on the subtracted value. The phase of the analog signal is adjusted (S1002).

  Even if the first and second analog signals are 0, the multiplication unit 74, the detection unit 76, and the like may output an offset value instead of 0. Even in such a case, according to the analog modulation circuit 20 according to the present modification, the influence of the offset value can be removed, so that the skew between the first analog signal and the second analog signal can be accurately performed. Can be measured.

  FIG. 7 shows an integration signal Vo with respect to the phase difference θ caused by skew when the first analog signal is a sine wave signal and the second analog signal is a cosine wave signal. Next, a third modification of the present embodiment will be described. The analog modulation circuit 20 according to the present modification employs substantially the same configuration and function as the analog modulation circuit 20 shown in FIG.

  The slope (differential value) of the integrated signal Vo with respect to the phase difference θ caused by the skew when the sine wave signal and the cosine wave signal are output to the signal generator 30 and the phase difference θ caused by the skew is taken on the horizontal axis is shown in FIG. As shown in FIG. 7, the phase difference becomes maximum at θ = 0 (that is, when the phase shift amount between the sine wave signal and the cosine wave signal is 90 degrees), and gradually decreases as the phase difference θ moves away from 0. . Therefore, the skew adjustment unit 78 controls the phase of the sine wave signal and the cosine wave signal so that the skew becomes zero by controlling the differential value obtained by differentiating the level of the integrated signal Vo with the phase difference θ to be maximum. Can be adjusted.

  Therefore, the signal control unit 72 according to the present modification causes the signal generator 30 to output the first analog signal and the second analog signal in which the phase difference θ sequentially changes. For example, the signal control unit 72 may output a sine wave signal and a cosine wave signal in which the phase difference θ sequentially changes. Then, the skew adjusting unit 78 according to the present modification measures the level of the integrated signal Vo for each phase difference θ, and the signal generator 30 outputs based on the differential value obtained by differentiating the level of the integrated signal Vo with the phase difference. The phase of the first analog signal and the second analog signal to be adjusted is adjusted. When a sine wave signal and a cosine wave signal whose phase difference θ sequentially changes are output from the signal generator 30, the skew adjuster 78 outputs the signal generator 30 so that the differential value becomes maximum. The phases of the first analog signal and the second analog signal may be adjusted.

  Thereby, the skew adjustment unit 78 causes the phases of the first analog signal (for example, sine wave signal) and the second analog signal (for example, cosine wave signal) output from the signal generating device 30 so that the skew becomes zero. Can be adjusted. Further, the differential value obtained by differentiating the level of the integration signal Vo with the phase difference does not change even if the signal output from the detection unit 76 includes an offset. Therefore, according to such an analog modulation circuit 20, even when an offset is included in the signal output from the detection unit 76, the skew can be measured with high accuracy.

  FIG. 8 shows a configuration of an analog modulation circuit 20 according to a third modification of the present embodiment. Since the analog modulation circuit 20 according to this modification employs substantially the same configuration and function as the analog modulation circuit 20 shown in FIG. 2, members having substantially the same configuration and function are denoted by the same reference numerals in FIG. The description will be omitted except for the differences.

  The detection device 70 according to this modification further includes a local signal adjustment unit 92 and a register 94. The local signal adjustment unit 92 is configured to shift the shift unit so that the phase difference between the signal output from the I-side multiplication unit 54 in the operation circuit 50 and the signal output from the Q-side multiplication unit 58 in the operation circuit 50 becomes a predetermined phase. The amount of phase shift at 56 is adjusted. The register 94 stores the level of the signal output from the detection unit 76 in a state where the local signal adjustment unit 92 has adjusted the phase shift amount in the shift unit 56. For example, the register 94 may store the level of the integration signal output from the integration unit 82 in a state where the local signal adjustment unit 92 has adjusted the phase shift amount in the shift unit 56.

  FIG. 9 shows a processing flow of the analog modulation circuit 20 according to the third modification of the present embodiment. FIG. 10 shows the frequency characteristics of the output signal in the analog modulation circuit 20 according to the third modification of the present embodiment.

  First, the analog modulation circuit 20 according to the third modification adjusts the phase shift amount of the shift unit 56 in the first adjustment phase (S1101). More specifically, the signal control unit 72 causes the signal generator 30 to output an I signal and a Q signal as the first analog signal and the second analog signal. Thereby, the signal generator 30 can output an I signal and a Q signal as the first analog signal and the second analog signal. Here, the I signal may be a sine wave signal having a predetermined frequency, and the Q signal may be a signal obtained by shifting the phase of the I signal by 90 degrees.

  When the I signal and the Q signal are output from the signal generator 30, the I-side multiplier 54 multiplies the I signal by a predetermined local signal, and the Q-side multiplier 58 outputs the Q signal to the shift unit 56. Multiply by local signal. Then, the output unit 60 adds the signal output from the I-side multiplier 54 and the signal output from the Q-side multiplier 58 and outputs a modulated signal. Then, the local signal adjustment unit 92 adjusts the shift amount of the shift unit 56 based on the modulation signal output from the output unit 60 so that the I signal and the Q signal are modulated by the local signal with high accuracy and orthogonality. adjust.

Here, when the I signal and the Q signal are accurately and orthogonally modulated by the local signal, the signal component of the low frequency (f _LO −f _X ) in the modulated signal and the high frequency (f _LO in the modulated signal). The difference from the signal component of + f _X ) increases. When the orthogonality is good, one of the signal component of the low frequency (f _LO −f _X ) or the signal component of the high frequency (f _LO + f _X ) is preferably approximately zero. The signal component of the low frequency (f _LO −f _X ) includes a signal component of a frequency obtained by subtracting the frequency (f _X ) of the I signal from the frequency (f _LO ) of the local signal, and the high frequency ( The signal component of f _LO + f _X ) may include a signal component having a frequency obtained by adding the frequency (f _X ) of the I signal to the frequency (f _LO ) of the local signal.

Therefore, the local signal adjustment unit 92 has a signal component of the low frequency (f _LO −f _X ) in the modulation signal output from the output unit 60 and a signal of the high frequency (f _LO + f _X ) in the modulation signal. The phase shift amount of the shift unit 56 may be adjusted so that the level difference from the component becomes larger. Thereby, the local signal adjustment unit 92 can quadrature-modulate the I signal and the Q signal with high accuracy by the local signal.

  In the first adjustment phase, the analog modulation circuit 20 adjusts the phase shift amount of the shift unit 56 as described above, so that the signal generator 30 generates the first analog signal and the second analog signal. , Comprehensively corrects the skew and carrier phase difference generated in the path until the modulation signal is output from the output unit 60, and outputs a modulation signal obtained by accurately quadrature-modulating the first and second analog signals with the local signal can do.

  Next, in the storage phase, the register 94 stores the level of the signal output from the detection unit 76 in a state where the local signal adjustment unit 92 has adjusted the phase shift amount in the shift unit 56 (S1102). As an example, the register 94 may store the level of the integration signal output from the integration unit 82. In other words, the register 94 stores a value corresponding to the skew of the first and second analog signals output from the signal generator 30 in a state where the output signal (modulation signal) at the final stage is adjusted.

  Next, in the second adjustment phase after the local signal adjustment unit 92 adjusts the phase shift amount in the shift unit 56, the analog modulation circuit 20 performs the phases of the first and second analog signals output from the signal generator 30. Is adjusted (S1103). As an example, when the signal processing device 40 is removed and the analog modulation circuit 20 is attached to the signal generation device 30 corresponding to another pin resource, and after the adjustment in the first adjustment phase is completed, time elapses. When the temperature is changed, the phase adjustment in the second adjustment phase may be executed.

  More specifically, in the second adjustment phase, the skew adjustment unit 78 compares the level of the integration signal output from the detection unit 76 (for example, the integration unit 82) with the level of the integration signal stored in the local signal adjustment unit 92. The timing at which the signal generator 30 outputs the I signal and the Q signal is adjusted. That is, the skew adjustment unit 78 adjusts the timing at which the signal generator 30 outputs the I signal and the Q signal according to the amount deviated from the value stored in the storage phase.

  According to such an analog modulation circuit 20, a value corresponding to the skew of the first and second analog signals output from the signal generation device 30 when the modulation signal can be output with high accuracy as the entire device is stored in the register 94. Remember. Therefore, according to the analog modulation circuit 20 according to the present modification, when an error occurs in the previous stage of the signal processing device 40 (for example, the signal generation device 30), the signal generation is performed without changing the phase shift amount of the shift unit 56. The signal output from the device 30 can be quadrature-modulated with a local signal with high accuracy.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

1 shows a configuration of a test apparatus 10 according to an embodiment of the present invention, together with a receiving circuit 100 under test. 1 shows a configuration of an analog modulation circuit 20 according to an embodiment of the present invention. (A) shows an example of the first analog signal (sine wave signal), (B) shows an example of the second analog signal (cosine wave signal), and (C) shows the first analog signal and the second analog signal. (D) shows an example of a multiplication result when there is no skew between the first analog signal and the second analog signal. The 1st example (rectangular wave signal) of the 1st and 2nd analog signal output according to control of the signal control part 72 from the signal generator 30 which concerns on this embodiment is shown. The 2nd example (triangular wave signal) of the 1st and 2nd analog signal output according to control of the signal control part 72 from the signal generator 30 which concerns on this embodiment is shown. The processing flow of the analog modulation circuit 20 which concerns on the 1st modification of this embodiment is shown. The integrated signal Vo with respect to the phase difference θ when the first analog signal is a sine wave signal and the second analog signal is a cosine wave signal is shown. The structure of the analog modulation circuit 20 which concerns on the 3rd modification of this embodiment is shown. The processing flow of the analog modulation circuit 20 which concerns on the 3rd modification of this embodiment is shown. The frequency characteristic of the output signal in the analog modulation circuit 20 which concerns on the 3rd modification of this embodiment is shown.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Test apparatus 12 Waveform data generation part 14 Determination part 20 Analog modulation circuit 30 Signal generation apparatus 40 Signal processing apparatus 42 1st input terminal 44 2nd input terminal 50 Operation circuit 52 Local signal generator 54 I side multiplication part 56 Shift Unit 58 Q-side multiplication unit 60 output unit 70 detection device 72 signal control unit 74 multiplication unit 76 detection unit 78 skew adjustment unit 82 integration unit 92 local signal adjustment unit 94 register 100 receiving circuit under test

Claims (6)

A detection device for detecting a skew of first and second analog signals supplied in parallel from a signal generator to a signal processing device,
A signal control unit that causes the signal generator to output the first analog signal of a sine wave signal and the second analog signal of a cosine wave signal having substantially the same period as the first analog signal;
A multiplier that multiplies the first analog signal and the second analog signal output by the signal generator;
An integration unit that outputs an integration signal obtained by integrating the multiplication results in the multiplication unit ;
A skew adjustment unit that adjusts the phases of the first analog signal and the second analog signal output from the signal generator so that the absolute value of the level of the integral signal is minimized. ,
The signal control unit causes the signal generator to output the first analog signal and the second analog signal in which the phase difference sequentially changes,
The skew adjustment unit measures the level of the integrated signal for each phase difference, and the first analog output from the signal generator based on a differential value obtained by differentiating the level of the integrated signal with the phase difference. A detection device for adjusting a phase of a signal and the second analog signal . The detection device is provided in the signal processing device,
The signal processing device includes:
An input terminal for receiving the first analog signal and the second analog signal;
An operation circuit that receives the first analog signal and the second analog signal from the input terminal and operates according to the first analog signal and the second analog signal;
The multiplier receives the first analog signal and the second analog signal from the input terminal.
The detection device according to claim 1 . The signal generator outputs an I signal and a Q signal as the first analog signal and the second analog signal,
The operating circuit is
An I-side multiplier that multiplies the I signal by a predetermined local signal;
A shift unit that shifts the phase of the local signal by approximately 90 degrees;
A Q-side multiplier that multiplies the Q signal by the local signal output by the shift unit;
An output unit for adding and outputting the signal output from the I-side multiplication unit and the signal output from the Q-side multiplication unit;
The detection device includes:
A local signal adjustment unit that adjusts a phase shift amount in the shift unit so that a phase difference between a signal output from the I-side multiplication unit and a signal output from the Q-side multiplication unit becomes a predetermined phase;
A register that stores a level of an integration signal output from the integration unit in a state where the local signal adjustment unit has adjusted the phase shift amount in the shift unit;
The detection device according to claim 2 . After the local signal adjustment unit adjusts the phase shift amount in the shift unit, the level of the integration signal output from the integration unit is compared with the level of the integration signal stored in the register, and the signal generator A skew adjustment unit for adjusting timing of outputting the I signal and the Q signal;
The detection device according to claim 3 . An analog modulation circuit that modulates and outputs the generated transmission signal,
A signal generator for generating an I signal and a Q signal of the transmission signal;
A signal processing device that receives the transmission signal from the signal generation device and modulates and outputs the transmission signal;
The signal processing device includes:
An I-side multiplier that multiplies the I signal received via the first input terminal by a predetermined local signal;
A shift unit that shifts the phase of the local signal by approximately 90 degrees;
A Q-side multiplier that multiplies the Q signal received via the second input terminal by the local signal output from the shift unit;
An output unit that adds and outputs the signal output from the I-side multiplier and the signal output from the Q-side multiplier;
A detection device for detecting a skew between the I signal received by the first input terminal and the Q signal received by the second input terminal;
The detection device includes:
To the signal generator, a signal control unit for outputting a second analog signal of the cosine wave signal having a first analog signal and said first analog signal is substantially the same period of the sine wave signal,
Branching from the first input terminal for receiving the first analog signal, branching from the second input terminal for receiving the second analog signal, the first analog signal and the second analog signal A multiplier for multiplying the signal;
An integration unit that outputs an integration signal obtained by integrating the multiplication results in the multiplication unit ;
A skew adjustment unit that adjusts the phases of the first analog signal and the second analog signal output from the signal generator so that the absolute value of the level of the integral signal is minimized. See
The signal control unit causes the signal generator to output the first analog signal and the second analog signal in which the phase difference sequentially changes,
The skew adjustment unit measures the level of the integrated signal for each phase difference, and the first analog output from the signal generator based on a differential value obtained by differentiating the level of the integrated signal with the phase difference. An analog modulation circuit for adjusting a phase of the signal and the second analog signal . A test apparatus for testing a receiving circuit under test,
An analog modulation circuit that modulates the generated transmission signal and outputs it to the receiving circuit under test;
A determination unit for determining a signal output from the circuit under test in response to a signal output from the analog modulation circuit;
The analog modulation circuit is
A signal generator for generating an I signal and a Q signal of the transmission signal;
A signal processing device that receives the transmission signal from the signal generation device, modulates the transmission signal, and outputs the modulated signal;
The signal processing device includes:
An I-side multiplier that multiplies the I signal received via the first input terminal by a predetermined local signal;
A shift unit that shifts the phase of the local signal by approximately 90 degrees;
A Q-side multiplier that multiplies the Q signal received via the second input terminal by the local signal output from the shift unit;
An output unit that adds and outputs the signal output from the I-side multiplier and the signal output from the Q-side multiplier;
A detection device for detecting a skew between the I signal received by the first input terminal and the Q signal received by the second input terminal;
The detection device includes:
To the signal generator, a signal control unit for outputting a second analog signal of the cosine wave signal having a first analog signal and said first analog signal is substantially the same period of the sine wave signal,
Branching from the first input terminal for receiving the first analog signal, branching from the second input terminal for receiving the second analog signal, the first analog signal and the second analog signal A multiplier for multiplying the signal;
An integration unit that outputs an integration signal obtained by integrating the multiplication results in the multiplication unit ;
A skew adjustment unit that adjusts the phases of the first analog signal and the second analog signal output from the signal generator so that the absolute value of the level of the integral signal is minimized. See
The signal control unit causes the signal generator to output the first analog signal and the second analog signal in which the phase difference sequentially changes,
The skew adjustment unit measures the level of the integrated signal for each phase difference, and the first analog output from the signal generator based on a differential value obtained by differentiating the level of the integrated signal with the phase difference. A test apparatus for adjusting a phase of a signal and the second analog signal .

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