KR100745941B1 - Phase control method - Google Patents

Abstract

Even if discontinuity in phase occurs when switching the control voltage due to temperature change or the like, an object of the present invention is to realize a phase synthesized diversity receiver capable of stable control.

In the phase shifter which performs 360 degree continuous phase control using a voltage control phase shifter, when the phase control range of a voltage control phase shifter is made into the predetermined range exceeding 360 degree, and switching the control voltage of a voltage control phase shifter to discontinuousness. The phase control method performs control to have hysteresis characteristics by changing the switching point of the control voltage when the phase is increased from the switching point of the control voltage when the phase is decreased.

Phase control method, wireless communication.

Description

Phase control method {PHASE CONTROL METHOD}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an example of the characteristics of control voltage-phase shift amount of a voltage controlled abnormalizer used in the present invention;

2 is a block diagram illustrating an example of a diversity receiver;

3 is a view for explaining an example of a control method of a general abnormal phase;

4 is a block diagram showing an example of a vector synthesizer;

5 is a view showing an example of the characteristics of the phase shift amount according to the control voltage of the conventional voltage control abnormality;

6 is a view for explaining an example of a control method of a voltage control abnormality;

7 is a view for explaining the case where the control phase becomes discontinuous in the control method of the voltage control abnormality;

8 is a view for explaining an example of the control method of the voltage control abnormality device used in the present invention;

9 is a block diagram showing an example of an ideal phase of the present invention;

It is a figure explaining an example of the control method of the voltage control abnormality machine used by this invention.

TECHNICAL FIELD This invention is applied to a wireless communication system and relates to phase control of radio parts, such as a diversity receiver and an array antenna.

2 shows a block diagram of a typical in-phase synthesized diversity receiver. 2 shows a variable outlier 101 which inputs a reception input signal B and changes it to a predetermined phase, and the reception input signal B is received by the variable outlier 101. Synthesizer 102 for synthesizing and synthesizing a signal (output of variable-deviator 101) and reception input signal A in phase with A), and variable-deviator 101 so that the output of synthesizer 102 is maximum. It is comprised by the phase controller 103 which performs phase control with respect to (circle). 3 shows an example of a control method of the variable phase shifter 101.

In FIG. 3, the upper end is used as the phase control value of the variable idealizer 101 (that is, the control value of the phase controller 103) and the lower end is used as the amplitude of the synthesized output (that is, the output of the synthesizer 102). In the same time slot, it is assumed that the phase control value at the upper end is reflected in the amplitude immediately at the lower end, and the control to the variable phase shifter 101 is relatively given. In addition, as a control method, the control which changes a fixed phase control amount for every time slot and makes a synthesis amplitude maximum is performed.

In FIG. 3, the reception input signals A and B are in phase with each other in the state of the time slot t ₃ .

In time slots t ₁ to t ₃ , the combined amplitude increases as the phase control value increases. However, in the time slot t ₄ , since it is shifted from the optimum phase, it does not become the maximum amplitude, but rather the amplitude decreases from the maximum amplitude. For this reason, the time slot (t ₅₎ in the control to reduce the phase control value is executed, since the amplitude again increases with the control, and executes the control to reduce the phase at the next time slot (t ₆₎ of the. Since the synthesized amplitude decreases here, the operation of increasing the phase is performed in the next time slot t ₇ . In this way, a diversity receiver for performing phase synthesis is configured by varying by a constant phase control amount for each time slot so that the amplitude after synthesis is maximized.

As the variable outlier 101, for example, a vector synthesis abnormality unit shown in FIG. 4, a voltage controlled variable abnormality unit showing characteristics in FIG. 5, and the like are used.

The vector synthesizing phase shifter in FIG. 4 is an ideal phaser 301 that outputs an output signal in which one received input signal (RF signal) Ei is a phase 0 ° as it is and an output signal in which the phase is changed by 90 ° (orthogonal phase). ), The multipliers 302 and 303 multiplying the given coefficients and the synthesizer 304 for synthesizing and outputting the outputs of the multipliers 302 and 303. In FIG. 4, if the control to delay the phase of the input signal Ei is performed by the phase θ, the 0 ° output of the phase shifter 301 is multiplied by the cos θ being given as a coefficient to the multiplier 302, and the phase shifter 301 is multiplied. For the 90 ° output of, the phase can be varied by θ by giving sinθ to the multiplier 303 as a coefficient and multiplying it and then synthesizing it.

Fig. 5 shows the characteristics of the amount of phase shift with respect to the control voltage of the variable phase shifter of the voltage control type. In FIG. 5, a phase control is possible linearly from 0 degree to 360 degree according to a control voltage.

FIG. 6 shows control in the case where the control value changes from the upper limit or the lower limit of the control voltage, such as 0 ° to 360 ° or 360 ° to 0 ° using the ideal phase of FIG. 5. 6 (a) shows a case of control for increasing the phase control value and FIG. 6 (b) shows a case of control for decreasing the phase control value.

In practice, since it varies in units of a constant phase control amount, for example, in units of 1 °, the control range is 0 ° to 359 °, and the switching of the control voltage is performed as 0 ° to 359 ° or 359 ° to 0 °, For convenience of explanation, it is assumed that the same phase point rotated from 0 ° to 360 ° is rotated one time.

When the phase combining type diversity receiver circuit is to be realized in the 10 GHz band, for example, the vector synthesis abnormality device as shown in Fig. 4 does not secure sufficient accuracy in each element, and the reception quality is degraded or the apparatus becomes expensive. Practical problems can occur. In particular, the received signal is a characteristic degradation factor for a received signal having a large number of bits per symbol, such as 64 Quadrature Amplitude Modulation (64QAM) or 256QAM, such as a modulation signal using a multicarrier such as Orthogonal Frequency Division Multiplexing (OFDM).

Also in the voltage-controlled ideal phase of FIG. 5, even if the phase control value is changed from 0 ° to 360 ° or from 360 ° to 0 ° as shown in FIG. 6, the output phase as shown in FIG. 7 due to temperature fluctuations or the like. An error may occur so that a control range of 0 ° to 360 ° may be a control range such as, for example, -10 ° to 350 °. In this case, the control is possible only by the change of the phase control value to be moved at once in the range where the discontinuous switching of the control voltage does not occur, but in the case of the control passing through the switching points (0 °, 360 °) of the control voltage, FIG. As shown in the figure, even if the optimum phase point is different from the switch point, there is a possibility that a peak of the amplitude of the synthesized output occurs at this switch point, and the switch point may be mistaken as the optimum phase point.

An object of the present invention is to eliminate these drawbacks and to realize a phase synthesized diversity receiver capable of stable control even when phase discontinuity occurs during switching of control voltage due to temperature change or the like.

In order to achieve the above object, the present invention is to provide a phase control range of the voltage control outlier in a predetermined range of more than 360 ° in the outlier phase that performs continuous phase control of 360 ° using the voltage control outlier. When switching the control voltage of the voltage control abnormality to discontinuously, phase control for performing control to have hysteresis characteristics by changing the switching point of the control voltage when the phase is increased from the switching point of the control voltage when the phase is decreased. It is a way.

In addition, the phase control method is used to control a voltage control outlier that controls the phase of at least one received input signal in an in-phase synthesized diversity receiver.

Further, when the control voltage of the voltage control abnormality is switched discontinuously, the output of the voltage control abnormality is stopped for a predetermined period until the output phase is stabilized.

In addition, in the phase shifter performing continuous phase control of 360 ° using the voltage control phase shifter, a phase shifter for selecting one of two or more phase shifters and an output of the phase shifter includes a phase control range of each phase shifter. When the control voltage of the abnormal phase reaches the predetermined range, when the control voltage of the abnormal phase reaches the predetermined range, at least one control voltage of the abnormal phase which is not selected by the switching unit is first switched, and in phase with the abnormal phase selected by the switching phase. The control is performed so that the phase control method switches to the abnormal phase output selected by the switch at the predetermined switch point in the predetermined range.

In addition, the phase control method is used to control a voltage control outlier that controls the phase of at least one received input signal in an in-phase synthesized diversity receiver.

In addition, in the phase shifter which performs continuous phase control of 360 degrees using a voltage control phase shifter, it is provided with the switch which selects one or more of two or more phase shifters and the said phase shifter outputs, and the phase control range of each phase shifter is partly common. The control phase of the phase shifter when the control voltage of the phase shifter reaches the part of the common control range, and the control is performed such that the phase of the phase shifter not selected by the switch is in phase with the phase shifter selected by the switch; A phase control method for switching to an output of an abnormal phase selected by the diverter at a predetermined turning point in the range of.

In addition, the phase control method is used to control a voltage control outlier that controls the phase of at least one received input signal in an in-phase synthesized diversity receiver.

An example of the phase control characteristic of the abnormal phase (variable abnormal phase 101 of FIG. 2) used by this invention in FIG. 1 is shown. In the phase control of the conventional ideal phase of FIG. 5, the control range was 0 ° to 360 °. In FIG. 1 of the present invention, the control range is widened by + 20 ° from 0 ° to 380 °. Here, the extended control range may basically have a few degrees with respect to the first range 0 ° to 360 ° of the phase where the control is actually to be performed. For example, if the phase control step is used, the extended control range may have several steps. Do it. In addition, as an ideal group actually used, you may implement | achieve the said function with one ideal group, or you may implement | achieve a plurality of ideal groups.

The control characteristic at the time of using the phase shifter of the phase control characteristic of FIG. 1 is shown in FIG. In FIG. 8, it is assumed that the control voltage (output of the phase controller 103 in FIG. 2) is 380 degrees (i.e., +20 degrees) at the maximum, and 0 degrees at the minimum.

Fig. 8 (a) shows an example of control in the case of controlling in the direction of increasing phase, and Fig. 8 (b) shows an example of control in the case of controlling in the direction of decreasing in phase.

In the case of increasing the phase as shown in Fig. 8A, the control voltage is discontinuously switched to 0 ° because the phase is normally rotated by 360 °, but in the present invention, the control is continued as it is and 380 °. When it is, the control voltage is controlled to switch discontinuously from a voltage corresponding to 380 ° to a voltage corresponding to 20 °. On the contrary, when the control is executed to reduce the phase as shown in Fig. 8 (b), the switching is performed from 0 ° to 360 °.

In practice, since 20 ° to 0 ° corresponds to a section of 380 ° to 360 °, there is no change in being in the same phase even if the control voltage is switched anywhere therebetween. However, it is possible to have a difference of 20 degrees, that is, a hysteresis characteristic, in the case of performing the control to increase the phase by executing the control in this way and in the case of performing the control to reduce the phase.

For this reason, even if the output phase characteristic according to the control voltage in a variable abnormal phase changes with temperature fluctuation | variation, for example, and there exists a discontinuity of phase when switching a control voltage, there exists a margin about the control voltage immediately after switching, before and after. It is temporary and does not cause defects such as those occurring in the prior art.

In addition, since a control delay occurs when the control voltage is switched, the phase rotates 360 ° in the meantime. For this reason, when the present invention is used in the diversity receiver of Fig. 2, there are cases where an error such as a deterioration in reception quality occurs when the control voltage is switched. In such a case, it is possible to prevent the reception quality from deteriorating at least by stopping the output of the ideal phase for a certain period until the output phase of the variable phase ideal phase 101 of Fig. 2 becomes stable.

In addition, when it is possible to use a plurality of ideal phases, for example, as shown in FIG. 9, the first ideal phaser 901, the second abnormality phase 902, the switcher 903 and the phase comparator which switch outputs of two abnormal phases ( 904, for example, when the output of the first ideal phase 901 is selected by the switch 903 and outputted, as shown in FIG. 10, the control voltage has a specific period, i.e., a region where the control voltage is high and low. When the same phase falls within the controllable range in the region, the control voltage of the second phase shifter 902 is switched to a control voltage different from that of the first phase shifter 901 and the first phase shifter is used by using the phase comparator 904. When control is performed so that 901 and the second ideal phase 902 are in phase with each other, and switching to the control voltage of the first phase abnormality phase 901 is required, the output of the switch 903 is output to the second phase phase phaser 902. Switching of the control voltage by switching to the output of Also, if necessary, it is possible to prevent the disturbance of the phase.

In addition, it is also possible to control the phase control ranges of the first and second phase shifters 901 and 902 of FIG. 9 so as to overlap each other, and for example, to control the phase control range of the first phase shifter 901 from 0 ° to 190 degrees. The phase control range of the second phase shifter 902 from 180 ° to 370 °, and when the control of the first phase shifter 901 is from 180 ° to 190 °, the first phase shifter 901 and the second phase The control is performed so that the ideal phase 902 is in phase, and when the phase of the first phase 901 reaches 190 °, the switching unit 903 performs the switching to the second phase 902 and the second phase abnormality phase. When the control of 902 is from 360 ° to 370 °, the control is executed so that the first abnormal phase 901 and the second abnormal phase 902 become in phase, and the phase of the second abnormal phase 902 reaches 370 °. In this case, the phase control range of one of the phase shifters is narrower than 360 degrees by switching between the phase shifter 903 to the first phase shifter 901. The use is possible.

According to the present invention, even if phase discontinuity occurs at the time of switching the control voltage due to temperature change or the like, a phase synthesized diversity receiver capable of stable control can be realized. Further, even when the output phase of the abnormal phase is disturbed when the control voltage of the voltage controlling abnormal phase is discontinuous, it is possible to prevent deterioration in reception quality by not synthesizing the outputs during that time.

Further, by using a plurality of ideal phases, it is possible to realize a phase synthesized diversity receiver capable of continuously controlling the output phase.

Claims (7)

In the phase control method of the phase shifter which performs continuous phase control of 360 degrees using a voltage control phase shifter, The control voltage at the time of reducing the switching point and the phase of the control voltage in the case of increasing the phase when the phase control range of the voltage-controlled abnormality is set to a range exceeding 360 ° and the control voltage of the voltage-controlled abnormality is discontinuously changed. To control the hysteresis Phase control method. The method of claim 1, An in-phase synthesized diversity receiver for controlling a voltage control outlier for controlling the phase of at least one received input signal. Phase control method. The method according to claim 1 or 2, When the control voltage of the voltage control abnormality is switched discontinuously, the output of the voltage control abnormality is stopped for a period until the output phase is stable. Phase control method. In the phase control method of the phase shifter which performs continuous phase control of 360 degrees using a voltage control phase shifter, And a switching device for selecting two or more of the phase shifters and one of the outputs of the phase shifter, wherein the phase control range of each phase shifter is set to a range exceeding 360 °, and the control voltage of the phase shifter selected by the switch is 360 °. When the switching point in the over range is reached, the control voltage of any one of the abnormal phases not selected in the switching unit is first switched, and the control is performed to be in phase with the ideal phase selected in the switching unit, and then the selected switching point is selected at the switching point. Switching from the output of the phase shifter to the output of any one phase shifter Phase control method. The method of claim 4, wherein An in-phase synthesized diversity receiver for controlling a voltage control outlier for controlling the phase of at least one received input signal. Phase control method. In the control method of the ideal phase which performs 360 degree continuous phase control using a voltage-controlled phase shifter, A switching device for selecting two or more abnormal phases and one of the outputs of the abnormal phases, such that the phase control range of each abnormal phase has a part of a common control range, and the control voltage of the abnormal phase reaches the part of the common control range. Controlling the phase of any of the ideal phases not selected by the diverter to be in phase with the ideal phase selected by the diverter, and then switching from the output of the ideal phase selected by the diverter to the output of the one of the ideal phases at the switching point. doing Phase control method. The method of claim 6, Controlling a voltage controlled outlier controlling the phase of at least one received input signal in an in-phase synthesized diversity receiver Phase control method.

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