JP5122764B2 - Portable wireless device and control method of power amplifier used therefor - Google Patents

Description

  The present invention relates to a portable wireless device, and more particularly, to a power amplifier control technique for improving power consumption efficiency in a transmission control circuit by controlling power supplied to a power amplifier.

  FIG. 1 is a block diagram showing a configuration of a transmission control circuit provided in a conventional portable wireless device. The transmission control circuit 1 includes a control unit 2 that outputs a control signal corresponding to a power supply voltage (hereinafter referred to as PA power supply voltage) of a PA (power amplifier), and a power supply (battery) for driving the transmission control circuit 1. ), A battery voltage from the battery 4, a control signal from the control unit 2, and a DC / DC converter 3 that converts the battery voltage to a PA power supply voltage according to the control signal, and a DC / DC A high-frequency power amplifier circuit (mainly a power amplifier (hereinafter referred to as PA)) 5 that inputs a PA power supply voltage from the converter 3 and outputs high-frequency transmission power corresponding to the PA power supply voltage, and transmission power output by the PA5 Is detected and detected, and a detection unit 6 that outputs a detection signal to the control unit 2 and an AGC (Auto Gain Con) that adjusts the transmission power of the PA 5 based on the transmission power control signal from the control unit 2 trol) amplifier 7 is provided.

  In the transmission control circuit of the portable wireless device configured as described above, the battery voltage from the battery 4 is not constant because it gradually decreases with the consumption of power, and the necessary transmission power varies depending on the time. Therefore, the PA power supply voltage capable of improving the power consumption efficiency of the PA 5 varies depending on the time. Therefore, when the control unit 2 appropriately controls the PA power supply voltage via the control signal, the power consumption of the PA 5 can be made more efficient and the power consumption can be reduced.

  For example, by generating a PA power supply voltage corresponding to the transmission power, the power consumption of the PA 5 can be made more efficient and the power consumption can be reduced. Specifically, the control unit 2 acquires transmission power from the detection signal input from the detection unit 6, and generates a control signal for setting the PA power supply voltage to a (V) in a region where the transmission power is high. Further, a control signal for setting the PA power supply voltage to b (V) lower than a (V) is generated in a region where the transmission power is low. As described above, the control unit 2 generates the control signal for changing the PA power supply voltage stepwise by controlling the DC / DC converter 3 based on the transmission power.

  FIG. 2 is a diagram showing the PA power supply voltage with respect to the transmission power in the transmission control circuit 1 shown in FIG. The control unit 2 generates a control signal for the DC / DC converter 3 to convert the battery voltage into the PA power supply voltage shown in FIG. FIG. 3 is a flowchart showing a control procedure of the PA power supply voltage in the transmission control circuit 1 shown in FIG. The PA power supply voltage control procedure will be described below.

  When the transmission process starts, the control unit 2 inputs a detection signal from the detection unit 6 and acquires transmission power from the detection signal. Then, as shown in FIG. 2, it is determined whether or not the transmission power exceeds B (dBm) of the power supply voltage switching point from the bottom to the top (step S301). When it exceeds from the bottom to the top, a control signal for changing the PA power supply voltage to a (V) is generated and output to the DC / DC converter 3 (step S302). Thereby, PA5 inputs PA power supply voltage a (V) from DC / DC converter 3, and outputs transmission power by PA power supply voltage a (V).

  After the processing of step 302 is completed, or when it has not exceeded from the bottom to the top in step 301, the control unit 2 determines whether or not the transmission power has exceeded the power supply voltage switching point A (dBm) from the top to the bottom. Judgment is made (step S303). When it exceeds from the top to the bottom, a control signal for changing the PA power supply voltage to b (V) is generated and output to the DC / DC converter 3 (step S304). Thereby, PA5 inputs PA power supply voltage b (V) from DC / DC converter 3, and outputs transmission power by PA power supply voltage b (V).

  After the process of step 304 is completed, or when not exceeding from the top to the bottom in step 303, the control unit 2 determines whether or not the transmission process is completed (step S305). Exit. On the other hand, if the transmission process has not ended, the process returns to step 301.

  In this way, the PA power supply voltage is variable in two steps with hysteresis according to the transmission power, and is set large when the transmission power is large and set small when the transmission power is small. Therefore, it is possible to improve the efficiency of power consumption and reduce power consumption. In FIG. 2, the PA power supply voltage is varied stepwise, but in practice, it is varied in a fixed step having several stages of hysteresis.

  Patent Document 1 describes an example in which the power consumption of PA can be improved and the power consumption can be reduced. Similar to the transmission control circuit 1 shown in FIG. 1, this Patent Document 1 discloses a transmission control circuit in which the power supplied from the battery of the portable wireless device is varied by a DC / DC converter and supplied to the PA as a PA power supply voltage. Is described. Specifically, a transmission power reference value indicating a boundary between transmission power at which power loss does not occur and transmission power at which power loss occurs is compared with a transmission power designation value indicating a level of transmission power. When the specified value is equal to or less than the reference value, that is, when power loss occurs, control is performed so that the PA power supply voltage is lowered. In addition, the PA power supply voltage is controlled to be constant by using a power supply voltage table in which the PA power supply voltage corresponding to the power supply voltage monitoring value and the transmission power designation value is defined.

JP 2001-320288 A

  The transmission control circuit 1 shown in FIG. 1 and the transmission control circuit of Patent Document 1 (see FIGS. 7 to 9 of Patent Document 1) feed back the transmission power of the PA via the detection unit, and this fed back transmission power An APC (Auto Power Control) circuit that controls to supply a PA power supply voltage suitable for the above to the PA is provided. Since this APC circuit is a circuit for preventing the transmission power from becoming unstable due to the gain variation of PA, it is required to stabilize the transmission power.

  Here, with the transmission control circuit 1 shown in FIG. 1 and the transmission control circuit of Patent Document 1, it is possible to improve the power consumption of PA and reduce the power consumption. There was a problem that it was insufficient and wasted wasteful power. For example, in the transmission control circuit 1 shown in FIG. 1, the PA power supply voltage is varied in two steps step by step, but the maximum efficiency of the power consumption of the PA 5 does not change stepwise. Can be said to be consuming. In addition, the PA and the like constituting the transmission control circuit have different characteristics of the parts to be used, and the characteristics of the parts also change due to environmental factors such as temperature, so that the PA power supply voltage fluctuates. There was a problem of consuming wasteful power.

  Thus, in the transmission control circuit of the portable wireless device, there is a room for further reducing the power consumption of the PA. In order to realize this, it is desirable to vary the PA power supply voltage continuously rather than stepwise. However, if the PA power supply voltage is continuously varied, the transmission power changes drastically, and the PA characteristics change depending on the environment, so it is difficult to achieve the maximum efficiency of PA power consumption. It was.

  Accordingly, the present invention has been made to solve the above-described problems, and the object of the present invention is to reduce the power consumption of the PA by continuously varying the PA power supply voltage infinitely in the transmission control circuit of the portable wireless device. It is another object of the present invention to provide a portable wireless device capable of further improving efficiency and further reducing power consumption and a method for controlling a power amplifier used therefor.

In order to achieve the above object, a portable wireless device according to the present invention is a portable wireless device in which a voltage supplied from a battery is varied by a DC / DC converter and supplied to a power amplifier as a power supply voltage.
A reference value based on a temperature detection unit that detects the ambient temperature of the power amplifier, a storage unit that stores information on transmission power amplified by the power amplifier, and information on transmission power stored in the storage unit calculates a, the temperature detection unit by the detected temperature, and calculates a first correction value based on the transmission frequency in the transmission power, by using the reference value and the first correction value, the A control unit that controls the DC / DC converter, generates a control signal for varying the power supply voltage supplied from the DC / DC converter to the power amplifier, and outputs the control signal to the DC / DC converter; It is provided with.

In addition, the portable wireless device according to the present invention includes a transmission power detection unit that detects transmission power amplified by the power amplifier, and the control unit performs a second operation based on the transmission power detected by the transmission power detection unit. A correction value is calculated, the DC / DC converter is controlled using the reference value, the first correction value, and the second correction value, and the power supply voltage supplied from the DC / DC converter to the power amplifier A control signal for varying the frequency is generated, and the control signal is output to a DC / DC converter.

  In the portable wireless device according to the present invention, the storage unit stores transmission power scheduled to be amplified by the power amplifier, and the control unit calculates a control unit based on the scheduled transmission power. It is characterized by.

  Further, in the portable wireless device according to the present invention, the control unit is configured based on a difference between the transmission power detected by the transmission power detection unit and the transmission power scheduled to be amplified by the power amplifier. It is characterized by calculating.

  In the portable wireless device according to the present invention, the control unit outputs the second correction value, a delay from when the control signal is output until the predetermined transmission power is amplified via the DC / DC converter and the power amplifier. A portable wireless device that is calculated as a value corresponding to time.

The portable wireless apparatus according to the present invention, the control unit, for each update timing of the transmission power, and calculates the reference value and the correction value, and controls the DC / DC converter, wherein the said DC / DC converter A control signal for varying the power supply voltage supplied to the power amplifier is generated, and the control signal is output to a DC / DC converter.

Further, in the portable wireless device according to the present invention, the control unit calculates the reference value and the correction value at a preset timing of the transmission power update timing, and controls the DC / DC converter, A control signal for varying the power supply voltage supplied from the DC / DC converter to the power amplifier is generated, and the control signal is output to the DC / DC converter.

  Although the present invention has been described as a portable wireless device, the present invention can also be realized as a method substantially corresponding to these, and the present invention includes a method for controlling a power amplifier used in the portable wireless device. .

  According to the present invention, it is possible to further increase the efficiency of the power consumption of the PA and further reduce the power consumption.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 4 is a block diagram showing a configuration of a transmission control circuit provided in the portable wireless device according to the embodiment of the present invention. The transmission control circuit 11 includes a DC / DC converter 3, a battery 4 as a power source (battery), a PA (power amplifier) 5, a detection unit 6, an AGC (Auto Gain Control) amplifier 7, a control unit 12, and a temperature sensor unit 13. And a storage unit 14. When the conventional transmission control circuit 1 shown in FIG. 1 is compared with the transmission control circuit 11, the transmission control circuit 1 is the same in that the battery 4, the PA 5, the detection unit 6, and the AGC 7 are provided. And the storage unit 14, which differs from the control unit 2 in that it includes a control unit 12 having a different function. In the following, in FIG. 4, the same reference numerals as those in FIG.

  The temperature sensor unit 13 measures the environmental temperature of the transmission control circuit 11 and outputs a temperature signal to the control unit 12. The storage unit 14 stores a table necessary for the control unit 12 to generate a control signal, information on initial values, and the like. In addition, the temperature (environment temperature measured by the temperature sensor unit 13), control signal (voltage value of the control signal), detection signal (voltage value of the detection signal), detection signal for each scan at which the control unit 12 generates the control signal. The transmission power acquired from is stored.

  The AGC amplifier 7 adjusts the transmission power of the PA 5 based on the transmission power control signal from the control unit 12. The control unit 12 inputs a detection signal from the detection unit 6 to acquire transmission power, and inputs a temperature signal from the temperature sensor unit 13 to acquire the environmental temperature of the transmission control circuit 11. Also, various table information and initial value information and various information for each scan are input from the storage unit 14, and a control signal corresponding to the PA power supply voltage is generated based on these information, transmission power and temperature, and DC / Output to DC converter 3. In addition, a transmission power control signal for adjusting transmission power is output to the AGC amplifier 7. Further, for each scan for generating a control signal, the storage unit 14 stores the temperature, the control signal (voltage value of the control signal), the detection signal (voltage value of the detection signal), and the transmission power acquired from the detection signal.

  FIG. 5 is a diagram illustrating a configuration example of a table stored in the storage unit 14. (1) is a configuration example of the PA power supply voltage table Vt showing the relationship between the transmission power amplified by the PA5 and the voltage Vc of the control signal serving as a reference for determining the PA power supply voltage. Since the PA power supply voltage table Vt is determined by the characteristics and specifications of the DC / DC converter 3 and PA5, it is a table that is experimentally set depending on the components of the DC / DC converter 3 and PA5. The reference voltage Vc of the control signal is a value at the reference temperature and the reference transmission frequency. In addition, this configuration example includes a conversion mode and a through mode as the DC / DC mode. When the transmission power is 15 (dBm) or less, the conversion mode is selected, and when the transmission power exceeds 15 (dBm), the through mode is selected. Show. In the through mode, the DC / DC converter 3 outputs the input battery voltage as it is as the PA power supply voltage without performing the conversion process.

  (2) is a configuration example of the temperature correction table Tt showing the relationship between the temperature and the temperature correction value To for correcting the control signal. Since this temperature correction table Tt is determined by the characteristics of PA5, it is a table set experimentally depending on the parts of PA5.

  (3) is a configuration example of the frequency correction table Ft indicating the relationship between the transmission frequency and the frequency correction value Fo for correcting the control signal. This frequency correction table Ft is a table that is experimentally set depending on components such as PA5 because it is determined by the characteristics of PA5, a filter (not shown), and the like.

  (4) is a configuration example of the transmission power error table Pt showing the relationship between the detection voltage difference and the transmission power error correction value Po for correcting the control signal. The transmission power error correction table Pt is a table that is experimentally set depending on components such as PA5 because it is determined by the characteristics of PA5 and a filter (not shown).

  (5) is a configuration example of the PA power supply voltage delay correction table Dt showing the relationship between the power difference and the PA power supply voltage delay correction value Do for correcting the control signal. Here, the power difference is the transmission power acquired from the PA 5 (transmission power scheduled at the next timing) from the transmission power acquired through the detector 6 at the next timing (actually from the PA 5). This is a value obtained by subtracting the output transmission power. This PA power supply voltage delay correction table Dt is a table for correcting a delay that occurs when the PA power supply voltage changes and the transmission power changes in accordance with the change of the control signal to the DC / DC converter 3. This is to cope with a change in transmission power in time. The PA power supply voltage delay correction value Do is set in consideration of the amount of change in transmission power per unit time based on the time constant of the change in transmission power. Further, the correction of the control signal by the PA power supply voltage delay correction table Dt is particularly necessary when, for example, the control unit 12, the AGC amplifier 7, and the PA5 are provided with filters. When the transmission power is decreased by this correction, there is an effect that the transmission power is not unnecessarily decreased.

  FIG. 6 is a flowchart showing a PA power supply voltage control procedure by the transmission control circuit 11 shown in FIG. Hereinafter, a process in which the control unit 12 generates a control signal corresponding to the PA power supply voltage will be described. First, the control unit 12 receives the PA power supply voltage table Vt, temperature correction table Tt, frequency correction table Ft, transmission power error correction table Pt, initial value Pi of transmission power error correction, PA power supply voltage delay correction table from the storage unit 14. Dt and the initial value Di of the PA power supply voltage delay correction are read out to a buffer (not shown) (step S601). Thereafter, the first PA power supply voltage control process is performed in steps 602 to 605, and the second and subsequent PA power supply voltage control processes are performed in steps 609 to 614.

  The control unit 12 acquires preset power to be transmitted from a setting unit (modulator) (not shown), and uses the power to be transmitted and the PA power voltage table Vt as a reference control signal for determining the PA power voltage. Vc is calculated (step S602). Specifically, the control signal Vc for the power to be transmitted (transmission power) is calculated by linear interpolation using the PA power supply voltage table Vt.

The control unit 12 acquires the temperature from the temperature sensor unit 13, and acquires a preset transmission frequency from a setting unit (not shown) (step S603). Then, the control unit 12 calculates the temperature correction value To and the frequency correction value Fo using the acquired temperature, transmission frequency, temperature correction table Tt, and frequency correction table Ft (step S604). Specifically, the temperature correction value To with respect to the temperature is calculated by linear interpolation using the temperature correction table Tt. For example, when the temperature is 44 ° C., the group including this temperature is 7 in the temperature correction table Tt from FIG. 5B, and the temperature correction value To is calculated by linear interpolation as follows.
Temperature correction value To = (44−40) × ((6−3) / (50−40)) + 3 = 4.2
Here, 44 is the current temperature, 40 is the lower temperature of group 7, 6 is the higher correction value of group 7, 3 is the lower correction value of group 7, and 50 is the higher temperature of group 7 It is.
Further, the frequency correction value Fo for the transmission frequency is calculated by linear interpolation using the frequency correction table Ft.

The control unit 12 calculates an output value Co of the control signal using the following equation (step S605).
Co = Vc + To + Fo + Di + Pi
Here, Vc is a voltage value of a control signal serving as a reference for determining the PA power supply voltage, To is a temperature correction value, Fo is a frequency correction value, Di is an initial value of PA power supply voltage delay correction, and Pi is an initial value of transmission power error correction. Value. The initial value Di of PA power supply voltage delay correction and the initial value Pi of transmission power error correction are values stored in advance in the storage unit 14, and are set experimentally depending on components such as PA5.

  When the first PA power supply voltage control processing is completed in steps 602 to 605, the control unit 12 outputs a control signal to the DC / DC converter 3 (step S606), performs transmission power output processing, and transmits transmission power. A control signal is output to the AGC amplifier 7 (step S607).

  Then, it is determined whether or not the transmission is finished (step S608). If the transmission is not finished, the second PA power supply voltage control process is performed. The control unit 12 receives the detection signal from the detection unit 6, and acquires the current transmission power from the detection signal based on a preset relationship value between the detection signal and the transmission power (step S609).

  The control unit 12 calculates a difference between the current transmission power and the transmission power scheduled to be transmitted, and calculates a detection voltage difference corresponding to the power error from the relation value. Then, the transmission power error correction value Po is calculated using the detected voltage difference and the transmission power error correction table Pt (step S610). Specifically, the transmission power error correction value Po for the detection voltage difference is calculated by linear interpolation using the transmission power error correction table Pt of FIG. Further, the power difference is calculated by subtracting the transmission power acquired via the detector 6 from the power scheduled to be transmitted, and the PA power supply voltage delay correction table Dt in FIG. The power supply voltage delay correction value Do is calculated by linear interpolation (step S610).

  The control unit 12 uses a preset power to be transmitted, a PA power supply voltage table Vt, a transmission power error correction table Pt, and a PA power supply voltage delay correction table Dt, as a control signal Vc serving as a reference for determining the PA power supply voltage, The PA power supply voltage delay correction value Do and the transmission power error value Po are calculated (step S611).

  The control unit 12 acquires the temperature from the temperature sensor unit 13, and acquires a preset transmission frequency from a setting unit (not shown) (step S612). Then, the control unit 12 calculates the temperature correction value To and the frequency correction value Fo using the acquired temperature, transmission frequency, temperature correction table Tt, and frequency correction table Ft (step S613).

The control unit 12 calculates an output value Co of the control signal by the following equation (step S614).
Co = Vc + To + Fo + Do + Po
Here, Vc is a voltage value of a control signal serving as a reference for determining the PA power supply voltage, To is a temperature correction value, Fo is a frequency correction value, Do is a PA power supply voltage delay correction value, and Po is a transmission power error correction value.

  When the second PA power supply voltage control processing is completed in steps 609 to 614, the control unit 12 outputs a control signal to the DC / DC converter 3 (step S606), performs transmission power output processing, and performs transmission power. A control signal is output to the AGC amplifier 7 (step S607).

  Then, it is determined whether or not the transmission is finished (step S608). If the transmission is not finished, the third PA power supply voltage control process is performed. As described above, unless the transmission is finished, the processes of steps 609 to 614 and steps 606 and 607 are performed. If the end of transmission is determined, the transmission process ends.

  FIG. 7 is a diagram illustrating a first control timing example. As illustrated in FIG. 7, the control unit 12 performs the transmission power output process (transmission power update) in step 607 illustrated in FIG. 6 and the second and subsequent PA power supply voltages in steps 609 to 614 via step 608. The control process and the process of outputting the control signal in step 606 and updating the PA power supply voltage are repeated in order. For example, if the portable radio device having the transmission control circuit 11 shown in FIG. 4 is a CDMA mobile phone, it receives transmission from the base station and updates its transmission power every 1.25 ms by its control bit. Perform regularly. That is, the control unit 12 uses the control bit every 1.25 ms as a trigger to perform the transmission power output process (transmission power update) in step 607 and the second and subsequent PA power supply voltages in steps 609 to 614 via step 608. The control process and the process of updating the PA power supply voltage by outputting the control signal in step 606 are sequentially performed.

  FIG. 8 is a diagram illustrating a second control timing example. When the first control timing example shown in FIG. 7 is compared with this second control timing example, the control unit 12 performs step 609 via step 607 of the transmission power output process (transmission power update) and step 608. To 614, the second and subsequent PA power supply voltage control processes and the process of outputting the control signal of step 606 and updating the PA power supply voltage are repeated in order, but the second control is the same. The timing example is different in that, for example, the timing is not periodically performed in synchronization with the control bit but is performed when the control bit is recognized a plurality of times. In the above-described example, when the control bit reception cycle is 1.25 ms and the control timing recognizes the control bit five times, the transmission power output processing (transmission power update) of step 607 is performed every 6.25 ms. ), The PA power supply voltage control processing for the second and subsequent times in steps 609 to 614 through step 608 and the processing for updating the PA power supply voltage by outputting the control signal in step 606 are sequentially performed. This second control timing example is suitable for suppressing a power change in consideration of the amount of change in transmission power.

  As described above, according to the transmission control circuit 11 provided in the portable wireless device according to the embodiment of the present invention, the power consumption efficiency of the PA power supply voltage is considered in the first process in consideration of the characteristic change of the PA5 and the like. PA5 using the PA power supply voltage table Vt, temperature correction table Tt, frequency correction table Ft, initial value Pi of transmission power error correction, and initial value Di of PA power supply voltage delay correction set so as to enable A control signal corresponding to the PA power supply voltage to be supplied to is generated, and this control signal is output to the DC / DC converter 3. As a result, the PA power supply voltage is a reference control signal Vc calculated from the power scheduled to be transmitted, a temperature correction value To calculated from the temperature, a frequency correction value Fo calculated from the transmission frequency, an initial value Pi of transmission power error correction, And, it is controlled by the PA power supply voltage delay correction value Di. Therefore, the PA power supply voltage takes a value that takes into account various factors that affect the efficiency of power consumption of PA5. Therefore, the power consumption of PA5 can be made more efficient and power consumption can be reduced. It becomes.

  Further, according to the transmission control circuit 11, in the second and subsequent processes, the control signal corresponding to the PA power supply voltage to be supplied to the PA 5 using the transmission power error correction table Pt and the PA power supply voltage delay correction table Dt. And this control signal is output to the DC / DC converter 3. As a result, the PA power supply voltage is further derived from the detection voltage difference (the difference between the current detection voltage and the radio voltage corresponding to the previous transmission planned power, and the power error (current transmission power and previous transmission planned power)). It is controlled by the calculated transmission power error correction value Po and PA power supply voltage delay correction value Do. Therefore, the PA power supply voltage takes a value that takes into account various factors that affect the efficiency of power consumption of PA5. Therefore, the power consumption of PA5 can be made more efficient and power consumption can be reduced. It becomes.

  Further, according to the transmission control circuit 11, as in the first control timing example shown in FIG. 7, the transmission power output process, the PA power supply voltage control process, and the process of outputting the control signal and updating the PA power supply voltage Was repeated. As a result, the PA power supply voltage and the transmission power are updated in a scan with a short period close to continuity. Therefore, since the PA power supply voltage is a value that quickly follows changes in various factors that affect the efficiency of power consumption of PA5, the power consumption of PA5 can be further improved in efficiency and consumption. It becomes possible to realize further reduction of electric power.

  Further, according to the transmission control circuit 11, as in the second control timing example shown in FIG. 8, the transmission power output process, the PA power supply voltage control process, and the process of outputting the control signal and updating the PA power supply voltage Is performed at a predetermined timing. Thereby, the PA power supply voltage and the transmission power are updated at a predetermined timing. Therefore, the PA power supply voltage has such a value that the transmission power does not change suddenly with respect to changes in various factors affecting the efficiency of the power consumption of PA5. Power consumption can be reduced.

  FIG. 9 is a diagram showing the input / output characteristics of PA5. As shown in FIG. 9, PA5 cannot satisfy its specifications unless it is used in the linear region. Here, PA5 can be used efficiently if it is within a range that satisfies the specifications of PA5 and is close to the saturation point. The control unit 12 generates a control signal to the DC / DC converter 3 so as to operate near the saturation point of the PA 5, and generates a transmission power control signal to the AGC amplifier 7. Thus, power consumption can be reduced.

  FIG. 10 is a diagram comparing the PA power supply voltage according to the prior art, the PA power supply voltage according to the embodiment of the present invention, and the ideal PA power supply voltage when the maximum efficiency is realized. As shown in FIG. 10, by using the transmission control circuit 11 provided in the portable wireless device according to the embodiment of the present invention, the PA power supply voltage is ideally brought close to the PA power supply voltage when the maximum efficiency is realized. Is possible.

  The present invention has been described with reference to the embodiment. However, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the technical idea thereof. For example, the control unit 12 linearly corrects the correction value of the control signal using the PA power supply voltage table Vt, the temperature correction table Tt, the frequency correction table Ft, the transmission power error correction table Pt, and the PA power supply voltage delay correction table Dt. Each calculation is performed, but instead of using a table, calculation may be performed using an arithmetic expression. For example, a control signal Vc serving as a reference for determining the PA power supply voltage is calculated by a coefficient × transmission power, a temperature correction value To is calculated by a coefficient × temperature, a frequency correction value Fo is calculated by a coefficient × transmission frequency, and a transmission power error is calculated. The correction value Po may be calculated by the coefficient × detection voltage difference, and the PA power supply voltage delay correction value Do may be calculated by the coefficient × power difference.

  Further, in the first PA power supply voltage control process, the control unit 12 calculates the control signal output value Co = Vc + To + Fo + Di + Pi in steps 602 to 606 in FIG. 6, and outputs the control signal output value to the DC / DC converter. The initial value Pi of the transmission power error correction in this case is read from the storage unit 14 and used. However, the initial output of the control signal in the first PA power supply voltage control process is stored in the storage unit 14. The value may be stored in advance, and the initial output value of the control signal read from the storage unit 14 may be output to the DC / DC converter 3 without performing the processing of steps 602 to 606. In this case, there is no need to use the initial value Pi for transmission power error correction.

It is a block diagram which shows the structure of the transmission control circuit with which the conventional portable radio | wireless machine was equipped. It is a figure which shows PA power supply voltage with respect to the transmission power in the transmission control circuit of FIG. FIG. 2 is a flowchart showing a PA power supply voltage control procedure in the transmission control circuit of FIG. 1. It is a block diagram which shows the structure of the transmission control circuit with which the portable radio | wireless machine by embodiment of this invention was equipped. FIG. 5 is a diagram illustrating a configuration example of a table stored in a storage unit in the transmission control circuit of FIG. 4. It is a flowchart figure which shows the control procedure of PA power supply voltage. It is a figure showing the example of the 1st control timing. It is a figure which shows the 2nd example of control timing. It is a figure which shows the input-output characteristic of PA. It is a figure which compares PA power supply voltage.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,11 Transmission control circuit 2,12 Control part 3 DC / DC converter 4 Battery 5 Power amplifier (PA)
6 Detection unit 7 AGC amplifier 13 Temperature sensor unit 14 Storage unit

Claims (14)

In the portable radio device in which the voltage supplied from the battery is varied by the DC / DC converter and supplied to the power amplifier as the power supply voltage,
A temperature detector for detecting the temperature around the power amplifier;
A storage unit storing information about transmission power amplified by the power amplifier;
A reference value is calculated based on information related to transmission power stored in the storage unit, and a first correction value is calculated based on the temperature detected by the temperature detection unit and the transmission frequency in the transmission power. , the reference value and by using the first correction value, and controls the DC / DC converter generates a control signal for varying the power supply voltage supplied from the DC / DC converter to the power amplifier A control unit for outputting the control signal to a DC / DC converter;
A portable wireless device comprising: The portable wireless device according to claim 1, wherein
A transmission power detection unit for detecting transmission power amplified by the power amplifier;
The control unit calculates a second correction value based on the transmission power detected by the transmission power detection unit, and uses the reference value, the first correction value, and the second correction value to calculate the DC / DC A portable radio that controls a converter, generates a control signal for varying the power supply voltage supplied from the DC / DC converter to the power amplifier, and outputs the control signal to the DC / DC converter. Machine. The portable wireless device according to claim 1 or 2,
The storage unit stores transmission power scheduled to be amplified by the power amplifier,
The portable wireless device, wherein the control unit calculates a reference value based on the scheduled transmission power. The portable wireless device according to claim 2, wherein
The portable radio characterized in that the control unit calculates the second correction value based on a difference between the transmission power detected by the transmission power detection unit and the transmission power scheduled to be amplified by the power amplifier. Machine. The portable wireless device according to claim 2, wherein
The control unit calculates the second correction value as a value corresponding to a delay time from when the control signal is output until the predetermined transmission power is amplified via the DC / DC converter and the power amplifier. A portable radio device. In the portable wireless device according to any one of claims 1 to 5,
The control unit calculates the reference value and the correction value at each transmission power update timing, controls the DC / DC converter, and supplies the power supply voltage supplied from the DC / DC converter to the power amplifier. A portable wireless device that generates a control signal for changing and outputs the control signal to a DC / DC converter. In the portable wireless device according to any one of claims 1 to 5,
The control unit calculates the reference value and the correction value at a preset timing among transmission power update timings, controls the DC / DC converter, and transmits the DC / DC converter to the power amplifier. A portable wireless device that generates a control signal for varying the supplied power supply voltage and outputs the control signal to a DC / DC converter. In the control method of the power amplifier used in the portable wireless device that supplies the power amplifier with the voltage supplied from the battery as a power supply voltage by changing the voltage with a DC / DC converter.
Calculating a reference value based on information on transmission power amplified by the power amplifier;
Calculating a first correction value based on the ambient temperature of the power amplifier and the transmission frequency at the transmission power;
The step of the reference value and by using the first correction value, and controls the DC / DC converter generates a control signal for varying the power supply voltage supplied from the DC / DC converter to the power amplifier When,
Outputting the control signal to a DC / DC converter;
A control method characterized by comprising: In the control method of the power amplifier used for the portable wireless device according to claim 8,
Calculating a second correction value based on the transmission power amplified by the power amplifier;
Control for controlling the DC / DC converter using the reference value, the first correction value, and the second correction value, and varying the power supply voltage supplied from the DC / DC converter to the power amplifier. And a step of generating a signal. In the control method of the power amplifier used for the portable wireless device according to claim 8 or 9,
In portable radios,
A control method comprising calculating a reference value based on transmission power scheduled to be amplified by the power amplifier. In the control method of the power amplifier used for the portable wireless device according to claim 9,
A control method comprising calculating a second correction value based on a difference between transmission power amplified by the power amplifier and transmission power scheduled to be amplified by the power amplifier. In the control method of the power amplifier used for the portable wireless device according to claim 9,
And a step of calculating the second correction value as a value corresponding to a delay time from when the control signal is output to when the transmission power is amplified via the DC / DC converter and the power amplifier. Method. In the control method of the power amplifier used for a portable radio according to any one of claims 8 to 12,
The control method characterized in that the reference value and the correction value are calculated at each transmission power update timing. In the control method of the power amplifier used for a portable radio according to any one of claims 8 to 12,
The control method characterized in that the reference value and the correction value are calculated at a preset timing among transmission power update timings.

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