JP2008306270A - Power amplifying circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce loss in a power amplifying circuit which drives a capacitive load. <P>SOLUTION: The power amplifying circuit comprises a pre-amplifying circuit 110 and a BTL-connected amplifying circuit 140 for amplifying input signals Vin and Vip, generating output signals, and driving a piezoelectric loudspeaker 120 as a capacitive load, and a control section 130. The control section 130 detects the frequency of the input or output signal and controls the voltage supplied to the BTL-connected amplifying circuit 140 according to the result of frequency detection and the output signal of the comparator 132. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a power amplifier circuit, and more particularly to a technique for reducing power consumption when driving a capacitive load.

  In some cases, a capacitive load is used as a driving target of the power amplifier circuit (see, for example, Patent Document 1). FIG. 8 is a circuit diagram showing an example of a power amplifier circuit when a piezoelectric speaker is used as a capacitive load. As shown in this figure, the power amplifying circuit 240 employs a BTL (Bridged Transless) system in which an amplifying device 241a and an inverting amplifying device 241b are bridge-connected so that a large output can be obtained.

  The power supply voltage of the power amplifier circuit 240 is generated from a power supply 250 such as a lithium ion battery. In general, the piezoelectric speaker 220 requires a high drive voltage of 12 Vpp to 15 Vpp. For this reason, when a 3.7 V lithium ion battery is used, it is boosted to a necessary voltage using the charge pump 260 or the like and supplied as the power supply voltage of the power amplifier circuit 240.

9A and 9B are diagrams showing the frequency characteristics of the piezoelectric speaker 220. FIG. 9A shows the frequency-impedance characteristics, and FIG. 9B shows the frequency-output sound pressure characteristics. Since the piezoelectric speaker 220 has capacitance, as shown in FIG. 9A, the impedance becomes extremely low as the frequency increases. In addition, as shown in FIG. 9B, there is a characteristic that the output sound pressure decreases as the frequency decreases.
JP 51-132746 A

  Since the impedance of the piezoelectric speaker 220 becomes extremely low as the frequency increases, the current flowing through the power amplifier circuit 240 also increases at high frequencies. Since the piezoelectric speaker 220 has a high drive voltage, there is a problem that when the frequency becomes high, the loss in the power amplifier circuit 240 increases and the amount of heat generation also increases.

  If the value of the protective resistor R10 is increased in order to prevent an increase in current in the high frequency range, the output efficiency of the power amplifier circuit 240 will deteriorate. Further, if class D amplification is performed in order to reduce the loss in the power amplifier circuit 240, a large voltage switching is required, and measures against unnecessary radiation are required.

  The present invention has been made in view of such a situation, and an object of the present invention is to reduce loss in a power amplifier circuit that drives a capacitive load.

  In order to solve the above problems, a power amplifier circuit according to the present invention includes an amplifying unit that amplifies an input signal to generate an output signal to drive a capacitive load, and a frequency that detects the frequency of the input signal or the output signal. A detection means and a power supply control means for controlling the power supply voltage supplied to the amplification means according to the detection result of the frequency detection means.

  According to the present invention, since the power supply voltage supplied to the amplifying means is controlled according to the detection result of the frequency detecting means, the loss in the power amplifier circuit can be reduced by reducing the power supply voltage as necessary. . That is, even if the impedance decreases due to the high frequency and the current increases, the power consumption of the power amplifier circuit can be reduced by reducing the power supply voltage.

  More specifically, the power supply control means selectively supplies one of a high voltage and a low voltage as the power supply voltage to the amplification means, and when the frequency detected by the frequency detection means is less than the first frequency, A high voltage can be supplied to the amplification means. Thereby, sufficient output can be obtained when the frequency is less than the first frequency.

The power supply control means includes a comparison means for comparing the voltage of the input signal with a reference voltage,
In the case where the frequency detected by the frequency detection means is equal to or higher than the first frequency and lower than the second frequency, based on the comparison result of the comparison means, when the voltage of the input signal is equal to or higher than the reference voltage, the high voltage is When the voltage of the input signal is less than the reference voltage supplied to the amplifying means, the low voltage can be supplied to the amplifying means. As a result, the power supply voltage is dynamically switched when the frequency is equal to or higher than the first frequency and lower than the second frequency, so that loss is reduced when the input signal is small and sufficient output is obtained when the input signal is large. be able to.

  Further, in the case where the frequency detected by the frequency detecting means is equal to or higher than the second frequency and lower than the third frequency, based on the comparison result of the comparing means, the voltage of the input signal is equal to or higher than the reference voltage. When a voltage is supplied to the amplifying means, and the voltage of the input signal is less than the reference voltage, the low voltage is supplied to the amplifying means, and a predetermined time has elapsed after the voltage of the input signal becomes equal to or higher than the reference voltage. When the time has elapsed, it is preferable that the low voltage is supplied to the amplifying means regardless of the voltage of the input signal. When the frequency is increased, the load impedance is decreased and the loss in the amplification means is increased. However, according to the present invention, when the frequency is equal to or higher than the second frequency and lower than the third frequency, the voltage of the input signal is equal to or higher than the reference voltage. Since a low voltage is forcibly supplied to the amplifying means after a predetermined time has elapsed, excessive heat generation in the amplifying means can be suppressed and power consumption can be reduced.

  The power supply control means selectively supplies one of a high voltage and a low voltage as the power supply voltage to the amplification means, and amplifies the low voltage when the frequency detected by the frequency detection means is equal to or higher than the third frequency. Can be supplied to the means. As a result, when the frequency is equal to or higher than the third frequency, the power consumption of the power amplifier circuit can be reduced by lowering the power supply voltage even if the load impedance decreases and the current increases.

  Embodiments of the present invention will be described with reference to the drawings. First, an outline of the present invention will be described. FIG. 1 is a block diagram showing a basic configuration example of the present invention. In this figure, the case where the power amplifier circuit 10 drives the piezoelectric speaker 20 which is a capacitive load is taken as an example. For simplicity, the power amplifier circuit 10 uses a general inverting negative feedback amplifier circuit using an operational amplifier OpAmp and resistors R1 and R2. Of course, this may be constituted by a normal negative feedback amplifier circuit. The control unit 30 controls the power supply voltage ± Vd supplied to the operational amplifier OpAmp.

  The control unit 30 includes a power supply circuit that generates a high voltage 35 and a low voltage 36. The high voltage 35 and the low voltage 36 are switched by a switch 37 and selectively supplied as an output power supply 34 to the operational amplifier OpAmp. . Here, the high voltage 35 is ± VHi, the low voltage 36 is ± VLo, and VHi is higher than VLo. The switch 37 is switched according to a rule determined in advance by the power supply voltage setting unit 33 in accordance with the output results of the frequency detection unit 31 and the input voltage comparison unit 32. The frequency detection unit 31 detects the frequency of the output signal Vo of the power amplification circuit 10, and the input voltage comparison unit 32 determines whether the input signal Vi of the power amplification circuit 10 exceeds a predetermined voltage value. .

  FIG. 2 is a diagram illustrating an example of a rule serving as a criterion for switching the switch 37 by the power supply voltage setting unit 33. FIG. 2A illustrates a first example, and FIG. 2B illustrates another example. Is shown. In this example, the combination of the voltage division of the input signal Vi and the frequency division of the output signal Vo determines whether to use the high voltage 35 or the low voltage 36 as the power supply voltage. That is, the power supply voltage supplied to the power amplifier circuit 10 is adjusted by a combination of the level of the sound based on the input signal Vi and the magnitude.

  Here, the voltage division of the input signal Vi is divided into two cases, that is, a case where the voltage value is equal to or higher than a predetermined voltage value and a case where the voltage signal is less than the predetermined voltage value. It shall be divided into four areas. The determination of the frequency division may be performed using the signal output Vo as it is or by extracting a representative frequency, for example, a fundamental frequency. Further, the voltage classification may be performed using the input signal Vi as it is, or by extracting a value corresponding to the amplitude. The number of sections is not limited to this example.

  As shown in the figure, the control unit 30 always supplies the high voltage 35 to the power amplifier circuit 10 in the low frequency region. This is because the impedance of the piezoelectric speaker 20 is high in the low frequency region, so that a large current does not flow even if the input voltage is high, and the loss in the power amplifier circuit 10 is not a problem. Further, by always supplying the high voltage 35, sufficient driving can be realized even in a low frequency region where the output sound pressure characteristic of the piezoelectric speaker 20 is relatively low.

  In the middle and low frequency region, the high voltage 35 and the low voltage 36 are switched and supplied to the power amplifier circuit 10 by controlling the switch 37 according to the magnitude of the input signal. In other words, during the period when the input voltage is low, the power supply voltage is set to the low voltage 36 to reduce the loss in the power amplifier circuit 10. Note that the value of the low voltage 36 is desirably set to such a level that the predetermined amplification in the power amplifier circuit 10 can be performed when the input signal is small. On the other hand, when the input voltage is large, the power supply voltage is set to the high voltage 35 so that sufficient amplification can be performed for a large input signal.

  In the middle and high frequency range, as shown in FIG. 2B, a time limit is set in advance, and the high voltage 35 and the low voltage 36 are controlled by controlling the switch 37 according to the magnitude of the input voltage within the time limit. When the time limit elapses, the low voltage 36 is supplied to the power amplifier circuit 10 regardless of the input voltage. Since an input signal in which the middle and high frequency regions are continuous is considered to be rare, switching is limited to a time during which the temperature rise of the power amplifier circuit 10 does not become excessive due to continuous output. This is because priority is given to loss reduction and circuit protection.

  In the high frequency region, the low voltage 36 is always supplied to the power amplifier circuit 10. This is because the impedance of the piezoelectric speaker 20 becomes low and a large current flows in the high frequency region, so that the loss in the power amplifier circuit 10 is reduced by lowering the power supply voltage of the power amplifier circuit 10.

  Next, the present invention will be further described by taking an actual circuit as an example. FIG. 3 is a block diagram showing an example of the configuration of a piezoelectric speaker driving device to which the present invention is applied. In the example of this figure, the output to the piezoelectric speaker 120 is increased by using the BTL connection amplifier circuit 140 at the output stage of power amplification. Prior to the power amplification, the previous amplification circuit is configured to include a drive D that differentially amplifies the input signals (Vin, Vip) and outputs positive and negative phases and resistors R1 to R4 that determine amplification factors. 110 is provided. The drive D is supplied with VBIAS: 1.5V as a bias voltage, and the midpoint of the operating point is determined.

  The output signal of the preamplifier circuit 110 is compared with a predetermined voltage by the comparator 132, and the result is output to the control unit 130. Note that the comparator 132 compares two input signals with a reference voltage, and can be realized by, for example, a circuit as shown in FIG. That is, it can be constituted by a normal two-input comparator 132a and comparator 132b and an Or circuit 132c that operates based on the output results of both. As a result, when one of the two input signals becomes larger than the reference voltage, the comparator 132 outputs the Hi level.

  The BTL connection amplifier circuit 140 that drives the piezoelectric speaker 120 is obtained by bridge-connecting an amplifier 141a and an amplifier 141b. The amplification device 141 constituting the BTL connection amplification circuit 140 can be realized by a circuit using two transistors, TrN and TrP, as shown in FIG. 4B, for example. When the impedance of the piezoelectric speaker 120 decreases and a large current flows, a large amount of power is consumed by the resistor Rn. In this circuit, since it is not necessary to provide a protective resistor in series with the piezoelectric speaker 120, the piezoelectric speaker 120 can be efficiently driven by the output of the BTL connection amplifier circuit 140.

  The power supply voltage of the BTL connection amplifier circuit 140 is generated by a power supply 150 such as a lithium ion battery. When the voltage is low, the output voltage of the power source 150 is supplied as it is through the diode D1, and when the voltage is high, the output voltage of the power source 150 is boosted using the charge pump 160 and supplied. Instead of the charge pump 160, a boosting device such as a switching power supply may be used.

  In the example of this figure, when the voltage is low, that is, when the switch 137 is OFF, a voltage obtained by subtracting the voltage drop VF of the diode D1 from 3.7V of the power supply 150 is supplied as the power supply voltage of the BTL connection amplifier circuit 140. When the voltage is high, that is, when the switch 137 is ON, a voltage boosted to 7.4 V by the charge pump 160 is supplied as the power supply voltage of the BTL connection amplifier circuit 140. The reference voltage of the comparator 132 is 3.7V−0.3V = 3.4V when the voltage drop VF of the diode D1 is 0.3V.

  The control unit 130 will be described in detail. FIG. 5 is a block diagram illustrating a functional configuration of the control unit 130. As shown in the figure, the control unit 130 is based on the frequency region determination unit 131 that determines the frequency region of the output signal of the preamplifier circuit 110, the output result of the comparator 132, and the determination result of the frequency region determination unit 131. A switching determination unit 133 that switches the switch 137. These functional units may be realized by software or hardware.

  In this example, the frequency region determination unit 131 determines that the frequency is low when the frequency of the output signal of the preamplifier circuit 110 is less than 500 Hz, and determines that the frequency is medium or low when the frequency is 500 Hz or more and less than 5 kHz. When the frequency is 5 kHz or more and less than 10 kHz, it is determined that the frequency is medium to high, and when the frequency is 10 kHz or more, it is determined that the frequency is high. The determination result of the frequency band determination unit 131 is output to the switching determination unit 133.

  The switching determination unit 133 includes a first timer and a second timer. As described above, in the middle and high frequency region, when the period for switching between the high voltage 35 and the low voltage 36 has passed the time limit, control for switching to the low voltage is performed. The first timer is a timer that measures the time from when it is determined as a high voltage in the middle and high frequency range. When the first timer measures a predetermined time, the time is up, and the switch 137 is forcibly turned OFF to switch to a low voltage. For this reason, the time-up time of the first timer is determined from the viewpoint of protecting the BTL connection amplifier circuit 140 from a temperature rise. When the first timer expires, the measurement time is reset.

  The second timer is a timer that measures the continuous time when the comparator 132 continues to output Hi in the middle and high frequency range even after the first timer expires. That is, after the first timer has timed up and switched to a low voltage, it is considered that the temperature that has risen will decrease if a predetermined time elapses. For this reason, the time-up time of the second timer is determined in consideration of the temperature reduction capability of the BTL connection amplifier circuit 140. However, the second timer may be omitted. Note that when the detection frequency shifts from the middle to high frequency region to another region, the values of the first timer and the second timer are reset.

  FIG. 6 is a flowchart for explaining the processing of the control unit 130. In the middle and high frequency range, the rule shown in FIG. 2A is used. The control unit 130 acquires the determination result of the frequency region determination unit 131 (S101). As a result, when the frequency is low, the switch 137 is turned on to supply a high voltage to the BTL connection amplifier circuit 140 (S201).

  FIG. 7A is a diagram illustrating the relationship between the output waveforms of the amplification device 141a and the amplification device 141b and the power supply voltage when the frequency is low. As shown in the figure, the power supply voltage (thick line in the figure) is always supplied with a high voltage of 7.4V. Even if one of the amplifying device 141a and the amplifying device 141b is saturated on the GND side, the amplitude increases in such a way that the other compensates for the amplitude, and an output waveform that does not distort as desired can be obtained on the piezoelectric speaker 120 side. Note that the shaded portion in the figure is the collector-emitter voltage associated with the loss in the transistors TrN and TrP of the amplifier 141.

  If the determination result of the frequency band determination unit 131 is a high frequency, the switch 137 is turned OFF and a low voltage is supplied to the BTL connection amplifier circuit 140 (S501).

  If the frequency is medium to low, control is performed according to the output of the comparator 132 (S301). That is, when the input voltage is small and the comparator 132 is Lo output (S301: No), the switch 137 is turned OFF and the low voltage is supplied to the BTL connection amplifier circuit 140. On the other hand, when the input voltage is large and the comparator 132 is a Hi output (S301: Yes), the switch 137 is turned on and a high voltage is supplied to the BTL connection amplifier circuit 140 (S303).

  FIG. 7B is a diagram showing the relationship between the output waveforms of the amplifying apparatus 141a and the amplifying apparatus 141b and the power supply voltage when the frequency is medium to low. As shown in the figure, the power supply voltage (thick line in the figure) is supplied with a high voltage of 7.4 V when the input voltage is high, and with a low voltage of 3.4 V when the input voltage is low. That is, when the amplitude is small, the power loss is reduced by reducing the voltage of the transistor TrN of the amplifying device 141, resulting in an output waveform as shown by the broken line. On the other hand, when the amplitude is large, the necessary voltage amplitude can be output, so that the output waveform is as shown by the solid line. Note that the shaded portion in the figure is the collector-emitter voltage associated with the loss in the transistors TrN and TrP of the amplifier 141.

  When the determination result of the frequency band determination unit 131 is a medium to high frequency, first, it is determined whether the output of the comparator 132 is Hi (S401). If the output is Lo (S401: No), the switch 137 is turned OFF and a low voltage is supplied to the BTL connection amplifier circuit 140 (S402).

  On the other hand, when the output is Hi (S401: Yes), it is determined whether or not the first timer is running (S403). When the first timer is activated (S403: Yes), it indicates that the switching between the high voltage and the low voltage is continuously performed at the medium and high frequencies, and therefore, it is determined whether or not the first timer has timed out. (S404). If the first timer has not timed up (S404: No), the switch 137 remains ON and the time measurement of the first timer is continued (S405). When the first timer has expired (S404: Yes), the switch 137 is turned OFF because it is necessary to shift to a low voltage. In addition, the second timer is started to measure the period during which the voltage is shifted to the low voltage, and the first timer is reset (S406).

  As a result of determining whether or not the first timer is activated, if the first timer is not activated (S403: No), it is determined whether or not the second timer is activated (S407). When the second timer is not activated (S407: No), it means that the supply of a high voltage is started at a medium and high frequency, so that the switch 137 is turned on to supply the high voltage to the BTL connection amplifier circuit 140. The timing of the first timer is started (S408).

  On the other hand, when the second timer is running (S407: Yes), it means that the first timer has timed up and is forcibly shifted to a low voltage. It is determined whether or not (S409). As a result, when the second timer has timed up (S409: Yes), there is no problem even if the second timer is shifted to a high voltage, so the switch 137 is turned on and the high voltage is supplied to the BTL connection amplifier circuit 140. If the second timer has not expired (S409: No), the switch 137 is kept OFF and the time measurement of the second timer is continued (S411).

By repeatedly performing the above processing, the control unit 130 can appropriately control the power supply voltage supplied to the BTL connection amplifier circuit 140. In the above example, the frequency of the output signal is detected. However, the frequency of the input signal may be detected. Further, although the voltage of the input signal is compared with the reference voltage, the voltage of the output signal may be compared with the reference voltage.
In the above-described embodiment, the BTL connection amplifier circuit 140 has been described as an example of the amplifier circuit. However, the present invention is not limited to this, and the form thereof may be a single-ended amplifier circuit. Of course.
In addition, the frequency was divided into four such as low frequency, medium low frequency, medium high frequency, and high frequency, and the power supply voltage was controlled according to each division. Of course, voltage control may be executed.

It is a block diagram which shows the example of a fundamental structure of this invention. It is a figure which shows an example of the rule used as the criterion for a power supply voltage setting part to switch a switch. It is a block diagram which shows an example of a structure of the piezoelectric speaker drive device to which this invention is applied. It is a figure which shows the specific circuit structure of the amplifier which comprises a comparator and a BTL connection amplifier circuit. It is a block diagram which shows the function structure of a control part. It is a flowchart explaining the process of a control part. It is a figure which shows the relationship between the output signal of an amplifier, and a power supply voltage. It is a circuit diagram which shows an example of the power amplifier circuit at the time of using a piezoelectric speaker as a capacitive load. It is a figure which shows the frequency characteristic of a piezoelectric speaker.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Power amplifier circuit, 20 ... Piezoelectric speaker, 30 ... Control part, 31 ... Frequency detection part, 32 ... Input voltage comparison part, 33 ... Power supply voltage setting part, 34 ... Output power supply, 35 ... High voltage, 36 ... Low voltage , 37, switch, 110, preamplifier circuit, 120, piezoelectric speaker, 130, frequency detection means, 130, control unit, 131, frequency region determination unit, 132, comparator, 133, switching determination unit, 137, switch, 140,. BTL connection amplifier circuit, 141 ... amplifier, 150 ... power source, 160 ... charge pump, 240 ... power amplifier circuit, 220 ... piezoelectric speaker, 250 ... power source, 260 ... charge pump

Claims (5)

Amplifying means for amplifying the input signal and generating an output signal to drive a capacitive load;
Frequency detection means for detecting the frequency of the input signal or the output signal;
In accordance with the detection result of the frequency detection means, power supply control means for controlling the power supply voltage supplied to the amplification means,
A power amplifier circuit provided. The power control means includes
Selectively supplying one of a high voltage and a low voltage to the amplification means as the power supply voltage;
If the frequency detected by the frequency detection means is less than the first frequency, the high voltage is supplied to the amplification means;
The power amplifier circuit according to claim 1. The power control means includes
Comparing means for comparing the voltage of the input signal with a reference voltage,
In the case where the frequency detected by the frequency detection means is equal to or higher than the first frequency and lower than the second frequency,
Based on the comparison result of the comparison means, when the voltage of the input signal is greater than or equal to the reference voltage, the high voltage is supplied to the amplification means, and when the voltage of the input signal is less than the reference voltage, the low voltage To the amplification means,
The power amplifier circuit according to claim 1 or 2, The power control means includes
In the case where the frequency detected by the frequency detection means is equal to or higher than the second frequency and lower than the third frequency,
Based on the comparison result of the comparison means, when the voltage of the input signal is greater than or equal to the reference voltage, the high voltage is supplied to the amplification means, and when the voltage of the input signal is less than the reference voltage, the low voltage To the amplification means,
When a predetermined time elapses after the voltage of the input signal becomes equal to or higher than the reference voltage, the low voltage is supplied to the amplification unit regardless of the voltage of the input signal.
The power amplifier circuit according to claim 3. The power control means includes
Selectively supplying one of a high voltage and a low voltage to the amplification means as the power supply voltage;
If the frequency detected by the frequency detection means is equal to or higher than a third frequency, the low voltage is supplied to the amplification means;
The power amplifier circuit according to claim 1, wherein the power amplifier circuit is any one of claims 1 to 4.

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