RU2635270C1 - Power amplifier of sound frequency - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: amplifier consists of a level matching board, two or more identical output matching boards, a sound amplification module that consists of two or more identical audio frequency power amplifiers connected in parallel and made on integrated microcircuits with an input impedance (R_in) from 10 to 500 kΩ and an output peak current (I_outmax) from 4 to 30 A, and the number of output matching boards is equal to the number of audio power amplifiers of the sound amplification module.

EFFECT: increased level of the output power of the audio frequency when using a low-resistance load, with improving the quality of the audio signal and increasing the bandwidth of the audio frequency.

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Description

The claimed invention relates to the field of electrical and radio devices, in particular to amplification technology, and can be used as an audio power amplifier.

Known power amplifier audio frequency [Turuta E.F. Handbook "3500 chips of low-frequency power amplifiers and their analogues" (2nd edition revised and expanded). - M .: DMK Press, 2005, p. 116], containing the integrated circuit LM-3886TF and external elements of the circuit LM-3886TF.

The disadvantages of this technical solution are the low level of output power of the audio frequency, the low quality of the audio signal when using a low-impedance load (up to 4 ohms).

Known power amplifier audio frequency [Turuta E.F. Handbook "3500 chips of low-frequency power amplifiers and their analogues" (2nd edition revised and expanded). - M .: DMK Press, 2005., p. 223], containing the integrated microcircuit TDA1103SP and external elements of the microcircuit TDA1103SP.

The disadvantages of this technical solution are the low level of output power of the audio frequency, the low quality of the audio signal when using a low-impedance load (up to 4 ohms).

Known power amplifier audio frequency [Turuta E.F. Handbook "3500 chips of low-frequency power amplifiers and their analogues" (2nd edition revised and expanded). - M .: DMK Press, 2005, p. 240], containing the integrated microcircuit TDA7294S and external elements of the microcircuit TDA7294S.

The disadvantage of this technical solution is the low quality of the audio signal when using a low-impedance load (less than 4 ohms).

Known power amplifier audio frequency [Turuta E.F. Handbook "3500 chips of low-frequency power amplifiers and their analogues" (2nd edition revised and expanded). - M .: DMK Press, 2005, p. 240], containing the integrated microcircuit TDA7293 and external elements of the microcircuit TDA7293.

The disadvantage of this technical solution is the low quality of the audio signal when using a low-impedance load (less than 4 ohms).

Known power amplifier of sound frequency (sound amplification module), [Integrated amplifiers of low frequency / V. Gerasimov - 2nd ed., Revised. and add. - St. Petersburg: Science and Technology, 2003, p. 285], adopted for the prototype containing the integrated circuit TDA7294 and external elements of the integrated circuit TDA7294 (see Appendix).

As external elements of the TDA7294 integrated circuit in the prototype, the resistor R1 is used, one output of which is connected to the negative terminal of the capacitor C2, terminal SVR (IN + MUTE) of the microcircuit and the zero connection of the amplifier circuit, the other resistance terminal R1 is the negative input of the amplifier and is connected to the NON terminal INVERTING INPUT (IN +) microcircuit and non-polar capacitor C1, the other output of the isolation capacitor C1 is the positive input of the amplifier. Resistance R2 is connected to capacitor C2 by one output, connected to the inverse input of INVERTING INPUT (IN-) circuits by the other output, resistance R3 is connected in parallel to INVERTING INPUT (IN-) and OUT (OUT) outputs of the microcircuit, resistance R4 is connected to STAND-BY ( STBY) microcircuit, the other resistance terminal R4 is connected to the power supply (VSTBY), the resistance R5 is connected to the MUTE (MUTE) terminal of the microcircuit, the other resistance terminal R5 is connected to the power supply (VM), the capacitor C5 is connected in parallel to the BOOTSTRAP (BOOTSTRAP) and OUT (OUT) microcircuit, capacitor C3 under it is connected in parallel with the conclusions of STAND-BY GND (STBY-GND) and MUTE (MUTE) of the microcircuit, the capacitor C4 is connected in parallel with the conclusions of the STAND-BY GND (STBY-GND) and STAND-BY (STBY) microcircuits, one output of the capacitor C6 is connected to the + Vs (+ Vs) and + Vs (+ PWVs) of the microcircuit, the other terminal of the capacitor C6 is connected to the zero connection of the amplifier circuit, one terminal of the capacitor C7 is connected to the terminals + Vs (+ Vs) and + Vs (+ PWVs) of the microcircuit, the other terminal of the capacitor C7 is connected to the zero connection of the amplifier circuit, one terminal of the capacitor C9 is connected to the terminals -Vs (-Vs) and -Vs (-PWVs) of the microcircuit, the other terminal of the capacitor C9 is it is connected to the output of the STANDBY GND (STBY-GND) microcircuit, one output of the capacitor C8 is connected to the outputs -Vs (-Vs) and -Vs (-PWVs) of the microcircuit, the other output of the capacitor C8 is connected to the output of STAND-BY GND (STBY-GND) microcircuits.

The technical result of the invention is to increase the level of output power of the audio frequency (more than 200 W) when using a low-impedance load (up to 1 Ohm), improving the quality of the audio signal, as well as increasing the bandwidth of the audio frequency due to the parallel connection of UMZCH in an amount of two or more.

The specified technical result is provided by the proposed audio power amplifier. The amplifier contains a level matching board, the input of which is designed to connect to an audio signal source, two or more identical output matching boards, a sound amplification module, consisting of two or more identical sound frequency power amplifiers made on integrated circuits with an input impedance (R _in ) of 10 to 500 kOhm and output maximum current (I _out max) from 4 to 30 A. The number of output matching boards is equal to the number of audio power amplifiers of the sound amplification module. The positive output of the level matching board is simultaneously connected to the positive inputs of the audio power amplifiers of the sound amplification module, and the negative output of the level matching board is simultaneously connected to the negative inputs of the audio power amplifiers of the audio frequency of the sound amplifying module. The positive outputs of the audio power amplifiers of the sound amplification module are connected to the positive inputs of the respective output matching cards, and the negative outputs of the audio power amplifiers of the sound amplification module are connected to the negative inputs of the corresponding output matching boards. The positive output of the first output matching board is connected simultaneously to the positive outputs of all subsequent output matching boards and is the positive output of the amplifier for connecting the load. The negative output of the output matching board is connected simultaneously to the negative outputs of all subsequent output matching boards and is the negative output of the amplifier for connecting the load.

In FIG. 1 is a structural diagram of an audio frequency power amplifier in general form with the Nth number of output matching boards (PSV-I, PSV-II, ..., PCB-N), with a sound amplification module containing Ne the number of audio frequency power amplifiers (UMZCH- I, UMZCH-II, ..., UMZCH-N), where N denotes the serial number of UMZCH and PSV with more than two of them. In FIG. 2 is a schematic diagram of a level matching board (CCP 1). In FIG. 3 is an example of a circuit diagram of one of the identical sound frequency power amplifiers (UMZCH-I, UMZCH-II, ..., UMZCH-N) included in the sound amplification module 2. FIG. 4 is a schematic diagram of one of the identical output matching boards (PSV-I, PSV-II, ..., PSV-N). In FIG. 5 shows an example of a block diagram of an audio frequency power amplifier containing two output matching boards (PSV-I, PSV-II), respectively, 5 and 6 and a sound amplification module 2, containing two audio frequency power amplifiers (UMZCH-I, UMZCH-II ), respectively, 3 and 4. In FIG. Figure 6 shows an example of a block diagram of an audio frequency power amplifier containing four output matching boards (PSV-I, PSV-II, PSV-III, PSV-IV), respectively, 5, 6, 9, 10 and sound amplification module 2, containing four sound power amplifier (UMZCH-I, UMZCH-II, UMZCH-III, UMZCH-IV), respectively, 3, 4, 7, 8.

The audio frequency power amplifier consists of a level matching board (CCP) 1, a sound amplification module 2, consisting of two or more identical audio frequency power amplifiers (UMZCH-I, UMZCH-II, ..., UMZCH-N), respectively 3 and 4 ... k (where k is the serial number of the position in FIG. 1), identical output matching boards (PSV-I, PSV-II, ..., PSV-N), respectively, 5 and 6 ... h (where h is the serial number of the position in FIG. . one). Moreover, the number of output matching boards (PSV-I, PSV-II, ..., PSV-N) is equal to the number of sound frequency power amplifiers (UMZCH-I, UMZCH-II, ..., UMZCH-N). The input of the CCP 1 is intended for connection to an audio signal source. The positive output of the PSU 1 is simultaneously connected to the positive inputs of the audio power amplifiers UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k of the sound amplification module 2, and the negative output of the PSU 1 is simultaneously connected to the negative inputs of the audio power amplifiers UMZCH- I 3, UMZCH-II 4, ..., UMZCH-N k sound amplification modules 2. The positive outputs of sound power amplifiers UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k sound amplification modules 2 are connected to the positive inputs of the corresponding PSV-I 5, PSV-II 6, ..., PSV-N h, and negative outputs of power amplifiers The sound frequency UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k sound amplification modules 2 are connected to the negative inputs of the corresponding PSV-I 5, PSV-II 6, ..., PSV-N h. The positive output PSV-I 5 is connected simultaneously to the positive outputs PSV-II 6, ..., PSV-N h and is a positive (positive) output of the amplifier for connecting the load. The negative output PSV-I 5 is connected simultaneously to the negative outputs PSV-II 6, ..., PSV-N h and is the minus (negative) output of the amplifier for connecting the load.

The level matching board (CCP) 1 can be made, for example (see Fig. 2), from the trimming resistance R1 and resistance R2 connected in series. The output of the resistance R1 is the positive input of the CCP 1. The output of the resistance R2 is connected through the parallel connected inductor L1 and the resistance R3 to the positive output of the CCP 1. The output of the resistance R2 is connected through the parallel connected resistances R4 and R5 to the zero connection of the amplifier circuit and is the negative output of the CCP 1. The negative input of the CCP 1 is connected to the zero connection of the amplifier circuit.

Sound amplification module 2 consists of two or more identical sound frequency power amplifiers UMZCH-I 3, UMZCH-II 4, UMZCH-N k, each of which can be made in the form of an integrated circuit or external elements of an integrated circuit. The input and output parameters of the integrated circuit must correspond to the following data:

- input resistance of the microcircuit (R _in ) from 10 to 500 kOhm;

- output maximum current (I _out max) from 4 to 30 A.

In the following example of the operation of the invention, as each of the audio power amplifiers UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k sound amplification module 2 is used, for example, an audio power amplifier similar to the prototype and, accordingly, consisting of an integrated microcircuit TDA7294 and external elements of the microcircuit TDA7294 (see Fig. 3, which is similar to the circuit diagram of an audio frequency power amplifier adopted as a prototype and is given in the Appendix).

As the external elements of the TDA7294 integrated circuit, as in the prototype, a resistor R1 is used, one output of which is connected to the negative terminal of the capacitor C2, terminal SVR (IN + MUTE) of the microcircuit and the zero connection of the amplifier circuit, the other resistance terminal R1 is the negative input of UMZCH- I 3 and connects to the output of the NON INVERTING INPUT (IN +) circuits and non-polar capacitor C1, the other output of the isolation capacitor C1 is the positive input of the UMZCH-I 3 sound amplification module 2. Resistance R2 is connected to the condenser by one output S2, the other output is connected to the inverse input of the INVERTING INPUT (IN-) microcircuit, the resistance R3 is connected in parallel to the INVERTING INPUT (IN-) and OUT (OUT) outputs of the microcircuit, the resistance R4 is connected to the STAND-BY (STBY) output of the microcircuit, another output resistance R4 is connected to the power supply (VSTBY), resistance R5 is connected to the MUTE (MUTE) terminal of the microcircuit, another resistance terminal R5 is connected to the power supply (VM), capacitor C5 is connected in parallel to the BOOTSTRAP (BOOTSTRAP) and OUT (OUT) terminals of the microcircuit, capacitor C3 is connected in parallel with the terminals STAND-BY GND (STBY-GND) and MUTE (MUTE) m circuits, capacitor C4 is connected in parallel to the terminals of STAND-BY GND (STBY-GND) and STAND-BY (STBY) of the microcircuit, one terminal of capacitor C6 is connected to the terminals + Vs (+ Vs) and + Vs (+ PWVs) of the microcircuit, the other terminal of the capacitor C6 is connected to the zero connection of the amplifier circuit, one terminal of the capacitor C7 is connected to the terminals + Vs (+ Vs) and + Vs (+ PWVs) of the microcircuit, the other terminal of the capacitor C7 is connected to the zero connection of the amplifier circuit, one terminal of the capacitor C9 is connected to the -Vs terminals (-Vs) and -Vs (-PWVs) microcircuits, the other terminal of the capacitor C9 is connected to the output of the STAND-BY GND (STBY-GND) microcircuit, one pin One capacitor C8 is connected to the terminals -Vs (-Vs) and -Vs (-PWVs) of the microcircuit, another terminal of the capacitor C8 is connected to the terminal STAND-BY GND (STBY-GND) of the microcircuit.

The conclusions of the non-polar isolation capacitors C1 (external element of the TDA7294 chip) of each of UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k are connected to the positive output of the CCP 1 and are positive inputs of UMZCH-I 3, UMZCH-II 4, ... , UMZCH-N k. The terminals of the negative capacitors C1, the terminals of the resistance R1, the terminals SVR (IN + MUTE) of the microcircuit are connected to the negative output of the CCP 1, which is the negative input of each of UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k connected to the zero connection amplifier circuitry.

The negative input terminals UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k sound amplification module 2 are connected to the zero connection of the amplifier circuit and are the output negative terminals UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k . The OUT (OUT) conclusions of the microcircuits are the output positive conclusions of UMZCH-I 3, UMZCH-II 4, ..., UMZCH-N k.

PSV-I 5, PSV-II 6, ..., PSV-N h are identical and each of them can be made, for example (see Fig. 4), from a non-polar capacitor C2 and resistance R2 connected in series, and a non-polar capacitor C2 connected in parallel capacitors C1 and C3 connected in series, and the positive terminal of capacitor C1 connected to terminal C2 is the positive input of the PSV (PSV-I 5, PSV-II 6, ..., PSV-N h), the negative terminal of the capacitor C1 is connected to the negative terminal C3 according to the principle of non-polar inclusion, positive terminal cond The sensor C3 is connected to the output of the capacitor C2 connected to the resistance R2, the resistance R1 and R3 are connected in parallel to the resistance R2, the output of the resistance R2 is the positive output of the PSV (PSV-I 5, PSV-II 6, ..., PSV-N h). The input negative terminals PSV-I 5, PSV-II 6, PSV-N h are connected to the zero connection of the amplifier circuit and are the negative output terminals PSV-I 5, PSV-II 6, ..., PSV-N h.

Let us first consider an example No. 1 of operation of an audio frequency power amplifier (see Fig. 5), using an example of an amplifier including a level matching board (CCP 1), a sound amplification module 2 containing two sound frequency power amplifiers UMZCH-I 3, UMZCH-II 4, two boards for matching outputs PSV-I 5, PSV-II 6.

Then we consider an example No. 2 of operation of an audio frequency power amplifier (see Fig. 6), containing a level matching board (CCP 1), a sound amplification module 2, containing N> 2 UMZCH, for example, four (N = 4) audio frequency power amplifiers UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8, respectively, four boards for matching outputs PSV-I 5, PSV-II 6, PSV-III 9, PSV-IV 10.

Example No. 1 of the audio power amplifier.

We connect the audio signal source to the input terminals of the amplifier, which are the input of the PSU 1, and to the output terminals of the amplifier formed by parallel connection of the outputs PSV-I 5 and PSV-II 6, connect the load (speakers, etc.).

The input audio signal, the voltage of which is not more than 8 volts, is fed to the matching board of the CCP 1 level, which allows matching the input voltage of the audio signal to the required standard voltage (0.775 V), at which the sound amplification module 2 operates in the normal mode. The converted signal from the CCP 1 is fed to UMZCH-I 3 and UMZCH-II 4. To increase the output power of the sound signal from the sound amplification module 2, UMZCH-I 3 and UMZCH-II 4 are connected in parallel. The parallel connection of UMZCH-I 3 and UMZCH-II 4 allows you to distribute the input current supplied to the input of sound amplification module 2 into its components in accordance with the first Kirchhoff law. For example, when a current value equal to 10 mkA is received at the input of the sound amplification module 2, an input current arrives at the input of sound power amplifiers UMZCH-I 3 and UMZCH-II 4, the value of which will be 5 mkA. The distributed current is supplied to UMZCH-I 3 and UMZCH-II 4. Due to the distribution of the current flowing to UMZCH-I 3 and UMZCH-II 4, an improvement in the quality of the audio signal and an increase in the passband of the audio frequency at the output of the sound amplification module 2 are achieved. The amplified signal from UMZCH-I 3 is fed to the PSV-I 5 output matching board, and the amplified signal from UMZCH-II 4 is fed to the PSV-II 6 output matching board. The PSV-I 5 output matching board is designed to exclude interference between UMZCH-I 3 to work UMZCH-II 4. Payment coordination outputs PSV-II 6 before Classifi- cation to avoid interference UMZCH 4-II-I work UMZCH 3. Introduction circuit 5 PSV-I and PCI-II 6 allows to stabilize operation UMZCH connected in parallel. Parallel output signals from PSV-I 4 and PSV-II 5 are supplied to the load.

The signal is amplified by summing the output power UMZCH-I 3 and UMZCH-II 4 sound amplification module 2.

Example No. 2 of the audio power amplifier.

We connect the audio signal source to the input terminals of the amplifier, which are the input of the PSU 1, and to the output terminals of the amplifier formed by the parallel connection of the outputs PSV-I 5, PSV-II 6, PSV-III 9, PSV-IV 10, connect the load (speakers and etc.).

The input audio signal, the voltage of which is not more than 8 volts, is fed to the matching board of the CCP 1 level, which allows matching the input voltage of the audio signal to the required standard voltage (0.775 V), at which the sound amplification module 2 operates in the normal mode. The converted signal from the CCP 1 is fed to UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8 of the sound amplification module 2. To increase the output power of the sound signal from the sound amplification module 2, UMZCH-I 3 and UMZCH- II 4, UMZCH-III 7, UMZCH-IV 8 are connected in parallel. The parallel connection of UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8 allows you to distribute the input current supplied to the input of the sound amplification module 2 into its components in accordance with the first Kirchhoff law. The distributed current is supplied to UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8. For example, when a current amplification module 2 receives a current value of 20 mkA at the input of sound power amplifiers UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8 will receive the input current, the value of which will be equal to 5 mkA. Due to the distribution of the current flowing to UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8, an improvement in the quality of the sound signal and an increase in the passband of the audio frequency at the output of the sound amplification module are possible. -I 3 goes to PSV-I 5 output matching board, amplified signal from UMZCH-II 4 goes to PSV-II 6 matching output board, amplified signal from UMZCH-III 7 goes to PSV-III 9 matching output board, amplified signal from UMZCH-IV 8 is received on the PSV-IV 10 output coordination board. В-I 5 is designed to exclude the interference of the UMZCH-I 3 module on the operation of the modules UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8. The output coordination board PSV-II 6 is intended to exclude the interference of the UMZCH-II 4 module on the operation of the modules UMZCH-I 3, UMZCH-III 7, UMZCH-IV 8. The output coordination board PSV-III 9 is designed to exclude the interference of the UMZCH-III 7 module on the operation of the UMZCH-I 3, UMZCH-II 4, UMZCH-IV 8. Payment coordination of outputs PSV-IV 10 is designed to exclude the interference of the UMZCH-IV 8 module on the operation of the UMZCH-I 3, UMZCH-II 4, UMZCH-III modules 7. Introduction to the PSV-I 5, PSV-II circuit 6, PSV-III 9, PSV-IV 10 allows you to stabilize the operation of the UMZCH with parallel connection. Parallel output signals from PSV-I 5, PSV-II 6, PSV-III 9, PSV-IV 10 are supplied to the load.

The signal is amplified by summing the output power UMZCH-I 3, UMZCH-II 4, UMZCH-III 7, UMZCH-IV 8.

Thus, the proposed invention provides an increase in the level of output power of the audio frequency (more than 200 W) when using a low-impedance load (up to 1 Ohm), improving the quality of the audio signal, as well as increasing the bandwidth of the audio frequency due to the parallel connection of UMZCH in an amount of two or more.

Claims (1)

The audio frequency power amplifier consists of a sound amplification module, characterized in that it further comprises a level matching board, the input of which is designed to connect to an audio signal source, two or more identical output matching boards, and the sound amplification module consists of two or more identical sound power amplifiers frequencies performed on integrated circuits with an input impedance (R _in ) of 10 to 500 kOhm and an output maximum current (I _out max) of 4 to 30 A, and the number of output matching boards is the number of sound power amplifiers of the sound amplification module, while the positive output of the level matching circuit board is simultaneously connected to the positive inputs of the sound frequency amplifiers of the sound amplifying module, and the negative output of the level matching board is simultaneously connected to the negative inputs of the sound frequency amplifying sound module of the sound amplification module, positive outputs sound power amplifiers of the sound amplification module are connected to the positive inputs of the respective boards I have outputs, and the negative outputs of the audio power amplifiers of the sound amplification module are connected to the negative inputs of the corresponding output matching boards, the positive output of the first output matching board is connected simultaneously to the positive outputs of all subsequent output matching boards and is the positive output of the amplifier for connecting the load, the negative output of the board output matching is connected simultaneously to the negative outputs of all subsequent output matching boards and is tritsatelnym output amplifier to connect the load.

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