EA025998B1 - Acoustic digital-to-analogue converter (embodiments) - Google Patents

Abstract

The invention is related to acoustic D/A converters. The analogue path decreases, distortions reduce. Embodiments 4, 5 exclude parametric selection of components. Embodiment 5 provides low output resistance. DAC comprises a converter with a digital input and a differential current output. Embodiments 1-3: the converter controls current amplifiers, common outputs of which are connected to power supply (through current transducers in embodiments 2, 3) and power outputs are connected to an acoustic transformer (embodiment 1) or to current followers (embodiment 3). The current transducers, by means of tracking circuits, control amplifiers (embodiment 2) or current sources (embodiment 3). Embodiment 3: the current sources control the current followers connected to the acoustic transformer. Embodiment 4: the converter controls the current amplifier, the output of which is DAC output and, through the tracking circuit, adjusts the current generator connected to the DAC output. Embodiment 5: the converter controls the current followers that control, respectively, the voltage stabilizer and the current amplifier, the output of which is DAC output and is connected to the voltage follower and to the tracking circuit controlling the voltage follower.

Description

Technical field

The invention relates to electronics and radio engineering, in particular to electronic amplifiers, in particular to digital-to-analog audio frequency converters Ηί-Ρί, Ηί Εηά.

State of the art

Currently, digital media is almost the main source of information. New high-resolution digital formats are emerging. The processes of sound recording, mixing, mastering take place in a digital environment. And the concept of analog amplification was laid down a few decades ago and has not changed. To date, analogue correctors, equalizers, pre-amplifiers, terminal amplifiers, operational amplifiers directly in EEE or SI drives are widely used. Those. the common analog sound amplification path so far consists of numerous electronic parts connected in series: resistors, transistors, capacitors, transformers. At the same time, correctors, equalizers, pre-amplifiers, terminal amplifiers are connected in series by inter-unit connectors. This is the so-called method of sequential amplification of audio signals. He obviously has exhausted himself, since in every electronic component there is a loss of a piece of information. As a result, the microdynamics and overtone are significantly distorted. Obviously, the time has come to change the ideology of building the entire amplification path.

The prior art amplifiers, current-voltage converters, analog filters. To achieve high quality, these devices incorporate many electronic components, which is their drawback.

For example, an amplifier circuit using a digital-to-analog converter PCM1794 is known, which contains three operational amplifiers for each output channel PCM1794 (Lp: //№№№.y.ot/rtoyis1/rst1794). Digital data to the input of the PCM1794 comes from a data source, such as a controller or digital filter. The presence of three operational amplifiers leads to large non-linear distortions. The presence of feedback in operational amplifiers leads to dynamic distortion. The circuit lacks precise balancing of the output channel of the DAC. The current-voltage converter has a high input resistance. The scheme does not provide for the elimination of high-frequency differential common-mode noise.

Disclosure of inventions

The technical problem to which the claimed digital-to-analog audio converters (hereinafter referred to as audio DACs) are directed according to all the options is to improve the sound reproduction quality due to a significant reduction in the length of the sound path, reduction of distortions introduced by the converter.

The technical result achieved by the claimed technical solutions for all options is to reduce the length of the analog path, reduce distortion.

An additional technical result provided by the claimed inventions according to options 4 and 5 is the absence of the need for coordination (selection) of electronic components according to parameters.

An additional technical result provided by the claimed invention according to option 5 is to provide a low output impedance.

To achieve a technical result in all variants of the claimed inventions, it is proposed to abandon the usual sequential method of amplifying audio signals and integrate the digital-to-analog converter chip directly into the terminal amplifier. This significantly reduced the length of the audio analog path. Moreover, it is advisable to carry out all signal corrections directly in a digital device until information is received at the input of the devices of the claimed inventions. A new method is proposed - a powerful digital-current-current-current-voltage converter, which will be an amplifier. Method name: ITUC - digital-controlled current source. With this amplification concept, a lot of unnecessary amplification cascades, feedback circuits, as well as the most difficult cascade, the analog phase inverter, are eliminated.

The essence of the audio DAC according to option 1 is that the digital-to-analog converter contains a converter with a digital input and a differential current output. It differs in that the current output of the converter is connected by each of its two lines to the control input of one of the two current-controlled current amplifiers. The common outputs of the current amplifiers are connected to the first power input, and the power outputs are connected to the ends of the primary winding of at least one sound transformer. The midpoint of this winding is connected to a second power input. The ends of the secondary winding of this transformer are the analog output of the DAC.

The above essence is a combination of essential features of the claimed technical solution according to option 1, ensuring the achievement of the claimed technical result. A short analog output path and lack of feedback reduce distortion in the output signal.

In special cases, it is permissible to carry out the technical solution according to option 1 as follows. The input of the DAC through the input pulse transformer is connected to the input of a digital receiver, the output of which is connected to the digital input of the converter. Each of the current amplifiers is designed as a bipolar η-ρ-η transistor, the base of which is the control input of the current amplifier, the emitter is a common output, and the collector is a power output. The collectors of these transistors are connected to the ends of the primary windings of the two sound transformers, and the midpoint of these windings is connected to the second power input. The ends of the secondary windings of transformers are the analog outputs of the DAC. The DAC is equipped with tuning resistance included between the bases of the mentioned transistors. The tuning resistance slider is connected to the first power input.

The essence of the audio DAC according to option 2 is that the digital-to-analog converter contains a converter with a digital input and a differential current output; characterized in that the current output of the converter is connected by each of its two lines to the control input of one of two current-controlled current amplifiers. The common outputs of the current amplifiers are connected through the corresponding current sensors to the first power input. The power outputs of the current amplifiers together with the second power input are the analog output of the DAC. The outputs of the current sensors are connected to the signal inputs of the respective tracking circuits, the control outputs of which are connected to the control inputs of the respective current amplifiers.

The above essence is a combination of essential features of the claimed technical solution according to option 2, ensuring the achievement of the claimed technical result. A short analog output path and lack of feedback reduce distortion in the output signal. The refusal to use an audio transformer, as in option 1, allowed to reduce the weight of the audio DAC. At the same time, there was some restriction in the purpose of the audio DAC: with it, only an acoustic system can be used that performs the function of a current-voltage converter and contains speakers with two windings.

In special cases, it is permissible to carry out the technical solution according to option 2 as follows, the input of the DAC through the input pulse transformer is connected to the input of the digital receiver, the output of which is connected to the digital input of the converter. Each of the current amplifiers is made in the form of a bipolar transistor, the base of which is the control input of the current amplifier, the emitter is a common output, and the collector is a power output. The collectors of these transistors, together with the second power input, are the analog output of the DAC. Each tracking circuit is made in the form of an operational amplifier, in which the inverting input through a resistor is connected to the signal input of the tracking circuit; a non-inverting input through a resistor is connected to a reference input of the tracking circuit; the output through the resistor is connected to the control output of the tracking circuit;

the output through the capacitor is connected to a non-inverting input.

The essence of the audio DAC according to option 3 is that the digital-to-analog converter contains a converter with a digital input and a differential current output. It differs in that the current output of the converter is connected by each of its two lines to the control input of one of the two current-controlled current amplifiers. The common outputs of the current amplifiers are connected through the corresponding current sensors to the first power input. The power outputs of the current amplifiers are connected to the power inputs of the respective current repeaters. The outputs of the current repeaters are connected to different ends of the sound transformer and are analog outputs of the DAC. The midpoint of the sound transformer is connected to the second power input. The outputs of the current sensors are connected to the signal inputs of the respective tracking circuits, the control outputs of which are connected to the control inputs of the respective controlled current sources. The power output of each current source is connected to the control input of the corresponding current repeater, and through a resistor is connected to the second power input.

The above essence is a set of essential features of the claimed technical solution according to option 3, ensuring the achievement of the claimed technical result. A short analog output path and lack of feedback reduce distortion in the output signal.

In special cases, it is permissible to carry out the technical solution according to option 3 as follows. The input of the DAC through the input pulse transformer is connected to the input of a digital receiver, the output of which is connected to the digital input of the converter. In this case, each of the current amplifiers is made in the form of a bipolar pnp transistor, the base of which is the control input of the current amplifier, the emitter is a common output, and the collector is a power output. Each tracking circuit is made in the form of an operational amplifier, in which a non-inverting input through a resistor is connected to the signal input of the tracking circuit; an inverting input through a resistor is connected to a reference input of the tracking circuit; the output is connected to the control output of the tracking circuit;

the output through the capacitor is connected to the inverting input.

The controlled current source is made in the form of a pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output. Each current repeater is made cascode in the form of a composite transistor according to the Shiklai circuit with a p-type field effect transistor at the input and several bipolar p-p-p connected in parallel

- 2 025998 transistors. Moreover, the gate of this composite transistor is the input of the current repeater regulation, the source is the power input of the current repeater, and the drain is the output. In this case, the collector of the transistor of each current source is connected to the gate of the current repeater through a CS filter.

The essence of the audio DAC according to option 4 is that the digital-to-analog converter contains a converter with a digital input and a differential current output. It differs in that the current output of the converter is connected by one of its two lines to the control input of the current-controlled current amplifier. The common output of the current amplifier is connected to the first power input, and the power output is the analog output of the DAC and is connected to the signal input of the tracking circuit. The control output of the tracking circuit is connected to the control input of a controlled current source. The power output of the current source is connected to the control input of the controlled current generator, and through a resistor it is connected to the second power input. In this case, the current generator is connected between the second power input and the analog output of the DAC.

The above essence is a combination of essential features of the claimed technical solution according to option 4, ensuring the achievement of the claimed technical result, reducing the length of the analog path, reducing distortion. A short analog output path and lack of feedback reduce distortion in the output signal.

The use of one current amplifier, as well as a current balance controller containing a controlled current generator, a current source and a zero potential tracking circuit, eliminated the need to select electronic components according to the proximity of parameters when implementing the claimed technical solution according to option 4.

The refusal to use an audio transformer, as in option 3, allowed to reduce the weight of the audio DAC.

In special cases, it is permissible to carry out the technical solution according to option 4 as follows. The input of the DAC through the input pulse transformer is connected to the input of a digital receiver, the output of which is connected to the digital input of the converter. The current amplifier is made in the form of a composite transistor according to the Darlington circuit, in which the input bipolar pnp transistor is used to control the conductivity of another pnp transistor. Moreover, the base of the input transistor is the control input of the current amplifier, the connected emitters of the transistors of the Darlington circuit are the common output, and the connected collectors are the power output. The current output of the converter is connected by one of its lines to the base of the aforementioned input transistor, and the other by its line - through a diode - with the first power input. The tracking circuit is made in the form of an operational amplifier, in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit; an inverting input through a series circuit of two resistors is connected to the signal input of the tracking circuit;

the output is connected to the control output of the tracking circuit; the output through the capacitor is connected to the inverting input.

The controlled current source is made in the form of a pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output.

The controlled current generator can be made in the form of a composite transistor according to the Shiklai scheme with a p-type field effect transistor at the input and several bipolar p-p-p transistors connected in parallel. In this case, the gate of the composite transistor of the current generator is the control input of the current generator, the source is connected through the resistor to the second power input, and the drain is connected to the analog output of the DAC.

The controlled current generator can also be made in the form of two parallel-connected bipolar p-p-p transistors, the collectors of which are connected to the second power input, and the emitters with the analog output of the DAC. In this case, the bases of these transistors of the current generator are connected to the drain of a p-type field-effect transistor, the gate of which is the control input of the current generator, the source of this field-effect transistor is connected to a voltage divider connected between the second power input and the analog output of the DAC.

The essence of the audio DAC in option 5 is that the digital-to-analog converter contains a converter with a digital input and a differential current output. It differs in that the current output of the converter is connected by each of its two lines to the input of one of the two current repeaters. The common leads of the current repeaters are connected to a common power input. The output of one current follower is connected to the voltage regulator control input and is connected to the third power input via a load resistance. The output of another current follower is connected to a control input of a current-controlled current amplifier. The common output of the current amplifier is connected to the first power input. The power output of the current amplifier is the analog output of the DAC and is connected to the power input of the voltage follower. The output of the voltage follower is connected to the second power input. The analog output of the DAC is connected to the signal input of the tracking circuit, the reference input of which is connected to a common power output, and the control output is connected to the control input of the voltage follower.

The above essence is a combination of essential features of the claimed technical solution according to option 5, ensuring the achievement of the claimed technical result by reducing the length of the analog path, reducing distortion. A short analog output path and lack of feedback reduce distortion in the output signal.

The use of one current amplifier, as well as a voltage follower with a tracking circuit, eliminated the need to select electronic components according to the proximity of parameters when implementing the claimed technical solution according to option 5.

Low output impedance is provided by the use of a voltage follower.

The refusal to use an audio transformer, as in option 3, allowed to reduce the weight of the audio DAC.

In special cases, it is permissible to carry out the technical solution according to option 5 as follows. The input of the DAC through the input pulse transformer is connected to the input of a digital receiver, the output of which is connected to the digital input of the converter. The current repeaters are each made in the form of a bipolar rpn transistor, the collector of which is the output of the current repeater, the base is the common output, and the emitter is the input of the repeater. Between the output of the current repeater and the load resistance, a filter is included containing a choke and a capacitor.

The current amplifier can be made in the form of parallel-connected bipolar pnp transistors. In this case, the control input of the current amplifier is the connected base of transistors, the common output is connected through the resistor connected emitters of transistors, and the power output is connected collectors of transistors.

The current amplifier can also be made two-stage complementary. In this case, in the first cascade, a bipolar rpn transistor is used, and in the second, several bipolar rpp transistors connected in parallel. The control input of the current amplifier in this case is the base of the transistor of the first stage, and the power output is the connected emitters of transistors of the second stage.

The tracking circuit is made in the form of an operational amplifier, in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit; the inverting input through the serial circuit of two resistors is connected to the signal input of the tracking circuit, and the connection point of these resistors is connected to the reference input through a circuit of parallel-connected capacitor and two diodes, one of these diodes being connected to the reference input by the anode and the other by the cathode;

the output is connected to the control output of the tracking circuit; the output through the capacitor is connected to the inverting input.

The voltage follower is made in the form of a composite transistor according to the Shiklai circuit with a p-type field effect transistor at the input and several bipolar pp-transistors connected in parallel. The gate of the composite transistor of the voltage follower is the input of the voltage follower regulation, the source is the power input of the voltage follower, and the drain is the output.

The author of the technical solutions of the claimed group made prototypes of these solutions, the tests of which confirmed the achievement of the indicated technical results.

Brief Description of the Drawings

In FIG. 1 shows a diagram of the inventive audio DAC according to option 1;

in FIG. 2 is a diagram of a sound DAC according to example 1 of option 1;

in FIG. 3 is a diagram of the audio DAC according to option 2;

in FIG. 4 is a diagram of the audio DAC according to example 1 of option 2;

in FIG. 5 is a diagram of an audio DAC according to embodiment 3;

in FIG. 6 is a diagram of a sound DAC according to example 1 of option 3;

in FIG. 7 is a diagram of an audio DAC according to embodiment 4;

in FIG. 8 is a diagram of a sound DAC according to example 1 of option 4;

in FIG. 9 is a diagram of a sound DAC according to example 2 of option 4;

in FIG. 10 is a diagram of an audio DAC according to embodiment 5;

in FIG. 11 is a diagram of the audio DAC according to example 1 of option 5;

in FIG. 12 is a diagram of the audio DAC according to example 2 of option 5.

The implementation of the audio DAC according to option 1.

The inventive audio DAC (Fig. 1) has a digital input (1), which is connected through an input pulse transformer (2) to the input of a digital receiver (3). The output of the digital receiver (3) is connected to the digital input of the converter (4). The differential current output of the converter (4) is connected by each of its two lines to the control input of one of the two current-controlled current amplifiers (5). The common outputs of the current amplifiers (5) are connected and connected to the first DC power supply (16) with a voltage of ν ₁ through a measuring resistor. The power outputs of amplifiers (5) are connected to the ends of the primary windings of two sound transformers (6). The midpoint of these windings is connected to the second DC power input (17) with a voltage of ν ₂ .

The secondary winding of one sound transformer (6) through a parallel-connected capacitor is connected to the analog low-frequency output of the audio DAC.

The secondary winding of another sound transformer (6) is connected to the analog output of the high frequencies of the audio DAC. The primary winding of this transformer (6) is connected to the power output

- 4 025998 of one of the current amplifiers (5) through a series-connected capacitor.

The input pulse transformer (2) is designed to transmit rectangular pulses of digital data and simultaneously galvanic isolation of the digital input (1) from the remaining elements of the audio DAC.

The digital receiver (3) is designed to receive input data and transfer them to the converter (4), preferably in the format Ι ² δ. The power of the digital receiver (3) and converter (4) is supplied from a power source (not shown) connected to the first (16) and second (17) power inputs.

Converter (4) is designed to convert a digital sequence of data about an alternating signal at its digital input into current at its differential output.

In order to balance the currents, the audio DAC can be equipped with a tuning resistance (7) connected between the control inputs of the current amplifiers (5). The resistance slider (7) is connected to the first power input (16).

Examples of specific performance of the audio DAC according to option 1.

Example 1

Y ₁ = 0 V, ν ₂ = +12 V. The digital receiver (3) is made in the form of a δ / ΡΌΙΡ digital interface converter ^ M8804 manufactured by HUoNyup M1goy1es1goi1S8, United Kingdom (Yyr: // No.№; No.o1 £ 8opt1sgo.ot ) Converter (4) is made in the form of a digital-to-analog converter PCM1794A manufactured by Techak 1p81gitep18 1psogrog1eb. United States (AhuhluDksot), included in the scheme of work in ΜΟΝΟ mode for greater current return (Fig. 2). Each of the current amplifiers (5) is made in the form of a 28A5200 bipolar pnp transistor manufactured by TokPa 8uetuopbis1og, Japan (11ir: / Lu \ y \ u.5e11psopDo51iba.so. P / en8). The control input of the amplifier (5) is the base of the transistor, the common output is the emitter, and the power output is the collector. In the manufacture of an audio DAC according to this example, to ensure the greatest balance of quiescent currents (currents in the absence of a signal at the digital input (1)), it is necessary for amplifiers (5) to use transistors with the closest parameters. Transistors are mounted on an individual radiator. This takes into account that the less the device heats up, the more accurate and reliable it works. This is especially true for the mentioned transistors.

Description of the operation of the audio DAC according to option 1.

Before starting work, the digital input (1) is connected to the source of the encoded sound information stream, and the analog outputs are connected to the speakers (electrodynamic loudspeakers).

The digital signal from the input (1) through the input pulse transformer (2) is fed to a digital receiver (3), in which it is converted and also digitally supplied to the digital input of the converter (4). The current corresponding to the digital signal passes through the converter output lines (4) and the control circuits of the current amplifiers (5).

Amplified (balanced) currents pass through sound transformers (6), where they are summed. The windings of sound transformers (6) and speakers simultaneously perform the function of a quantization noise filter. With current balance, the second harmonic is suppressed. This suppression is the greater, the more accurately the balance of quiescent currents is established.

Thus, the current-voltage converter is the speakers themselves. The presence of transformers (6) prevents the appearance of direct voltage at the speaker terminals in the absence of a signal.

The implementation of the audio DAC option 2.

The inventive audio DAC according to option 2 (Fig. 3) is intended for use with speakers, at least one of which is equipped with two windings.

The audio DAC of option 2 has a digital input (1), which is connected through an input pulse transformer (2) to the input of a digital receiver (3). The input pulse transformer (2) is designed to transmit rectangular pulses of digital data and simultaneously galvanic isolation of the digital input (1) from the remaining elements of the audio DAC.

The output of the digital receiver (3) is connected to the digital input of the converter (4). The digital receiver (3) is designed to receive input data and transfer them to the converter (4), preferably in the format Ι ² δ. The digital receiver (3) and converter (4) are supplied with power from a power source (not shown) connected to the first (16) and second (17) DC power inputs with voltages ν ₁ and ν _2, respectively.

Converter (4) is designed to convert a digital sequence of data about an alternating signal at its digital input into current at its differential output.

The differential current output of the converter (4) is connected by each of its two lines to the control input of one of the two current-controlled current amplifiers (5). The common outputs of current amplifiers (5) are connected through the corresponding current sensors (8) to the first power input (16). Current sensors (8) are designed to measure current in the circuit of the common terminals of current amplifiers (5).

The outputs of the current sensors (8) are connected to the signal inputs of the corresponding tracking circuits (9), the reference inputs of which are connected to a reference voltage source (10). The reference voltage source is made consistent with current sensors (8) and provides at its output a value

- 5 025998 voltage, equal to the signal level from the current sensor (8) when the current gain for the amplifier (5) matches the structurally set value in the case when the converter (4) gives a current in the absence of information about the sound signal at its digital input (current peace).

The control outputs of the tracking circuits (9) are connected to the control inputs of the respective current amplifiers (5). In this case, the control output of the tracking circuit (9) is connected to the control input of that current amplifier (5), the current signal in the circuit of the common output of which is fed to the input of this tracking circuit (9). The tracking circuits (9) are designed to balance currents in the power output circuits of current amplifiers (5) (the current in the power output circuit of the current amplifier (5) coincides with the current in the common output circuit of this amplifier (5)).

The power outputs of the amplifiers (5) connected by the capacitor together with the second power input (17) are three lines of the analog output of the audio DAC. In this case, the analog output line connected to the second power input is designed to connect two speaker windings to the connection point, and the other two lines connected to the power outputs of amplifiers (5) are designed to connect the free ends of the two aforementioned speaker windings.

Examples of specific performance audio DAC option 2.

Example 1

Y ₁ = 0 V, ν ₂ = +40 V. The digital receiver (3) is made in the form of a δ / ΡΌΙΡ digital interface converter \ UM8804 manufactured by the company ХУоИзоп М1сгое1ес1гоп1С8, United Kingdom (Lair: // »» »; No. 1 £ 8Opt1sgo.ot ) The converter (4) is made in the form of a digital-to-analog converter PCM1794A manufactured by Techak 1p81gitep18 1psotrota1eb, USA ("""..jsot), included in the по mode for a higher current output (Fig. 4). Each of the current amplifiers (5) is made in the form of six parallel-connected bipolar p-p transistors 28A5200 manufactured by TokYa 8et1sopbis1og, Japan (S1p: // No. ».8et1sop.1o8Paa.s .. .. p / ep). The control input of the amplifier (5) is the connected base of transistors, the common output is emitters, and the collector is a power output. In the manufacture of an audio DAC according to this example, to ensure an accurate balance of the quiescent currents (currents in the absence of a signal at the digital input (1)), it is necessary for amplifiers (5) to use transistors with the closest parameters. Transistors are mounted on one common radiator. This takes into account that the less the device heats up, the more accurate and reliable it works. This is especially true for the mentioned transistors.

Current sensors (8) are made in the form of resistances of the corresponding power dissipation with the smallest possible permissible deviations and / or individually selected close values of electrical resistance. If the current sensors (8) have unequal parameters, then different voltage reference sources (10) should be used for different tracking circuits (9).

Each tracking circuit (9) is made in the form of an operational amplifier (11), in which the inverting input through a resistor is connected to the signal input of the tracking circuit (9); a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); the output through the resistor is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to a non-inverting input.

The reference voltage source (10) can be made comprising a tuning resistor (12).

Description of the operation of the audio DAC according to option 2.

Before starting work, the digital input (1) is connected to the source of the encoded sound information stream, and the analog outputs are connected to the speaker (electrodynamic loudspeaker).

The digital signal from the input (1) through the input pulse transformer (2) is fed to a digital receiver (3), in which it is converted and also digitally supplied to the digital input of the converter (4). The current corresponding to the digital signal passes through the outputs of the converter (4) and the control circuits of the current amplifiers (5). Through the control circuit of the current amplifiers (5) also passes the control current flowing through the tracking circuit (9). The control inputs of the amplifiers (5) are the current adder.

Reinforced (balanced) currents pass through the speaker windings, where they are summed. The speaker windings simultaneously perform the function of a quantization noise filter. Precise balancing is ensured by tracking circuits (9), which also prevents the appearance of a constant voltage at the speaker terminals in the absence of a signal mode. Thus, the current-voltage converter is the speaker itself.

Tracking scheme (9) works as follows. If the current gain of the amplifier (5) is somewhat higher, then after turning on the power, the output of the corresponding current sensor (8) will receive a voltage that exceeds the reference voltage supplied by the source (10). At the control output of the tracking circuit (9), the current decreases. This will lead to a decrease in current through the control circuit of the amplifier (5), which will cause a decrease in the amplified current. Thus, the current amplifier (5) will produce a structurally predetermined current and the current balance will be maintained.

Implementation of the audio DAC according to option 3.

The inventive audio DAC according to option 3 (Fig. 5) has a digital input (1), which through the input

- 6 025998 pulse transformer (2) is connected to the input of the digital receiver (3). The input pulse transformer (2) is designed to transmit rectangular pulses of digital data and simultaneously galvanic isolation of the digital input (1) from the remaining elements of the audio DAC.

The output of the digital receiver (3) is connected to the digital input of the converter (4). The digital receiver (3) is designed to receive input data and transfer them to the converter (4), preferably in the format Ι ² δ. The digital receiver (3) and converter (4) are supplied with power from a power source (not shown) connected to the first (16) and second (17) DC power inputs with voltages ν ₁ and ν _2, respectively.

Converter (4) is designed to convert a digital sequence of data about an alternating signal at its digital input into current at its differential output.

The differential current output of the converter (4) is connected by each of its two lines to the control input of one of the two current-controlled current amplifiers (5). The common outputs of current amplifiers (5) are connected through the corresponding current sensors (8) to the first power input (16). Current sensors (8) are designed to measure current in the circuit of the common terminals of current amplifiers (5).

The power outputs of the amplifiers (5) are connected to the power inputs of the corresponding cascode current repeaters (15). Current repeaters (15) are used to set the current balance. The outputs of the two current repeaters (15) are connected to different ends of the sound transformer (6) and are analog outputs of the inventive sound DAC. The midpoint of this transformer (6) is connected to the second power input (17).

The outputs of the current sensors (8) are connected to the signal inputs of the corresponding tracking circuits (9), the reference inputs of which are connected to a reference voltage source (10). The reference voltage source is made consistent with the current sensors (8) and provides at its output a voltage value equal to the signal level from the current sensor (8) when the current gain for the amplifier (5) corresponds to the structurally set value in the case when the converter (4) gives a current in the absence of information about the sound signal at its digital input (quiescent current). The tracking circuits (9) are designed to balance currents in the power output circuits of current amplifiers (5) (the current in the power output circuit of the current amplifier (5) coincides with the current in the common output circuit of this amplifier (5)).

The control outputs of the tracking circuits (9) are connected to the control inputs of the respective controlled current sources (13). The common outputs of the current sources (13) are connected and connected to the third DC power input (18) with a voltage of ν ₃ . The power output of each current source (13) through a separate filter (14) is connected to the control input of the corresponding current repeater (15), and through a resistor (19) is connected to the second power input (17). In this case, the control output of the tracking circuit (9) is connected through a filter (14) to a current repeater (15) connected to that current amplifier (5), the current signal in the circuit of the common output of which is fed to the input of this tracking circuit (9).

Examples of specific performance audio DAC option 3.

Example 1

VI = -74 V, ν ₂ = 0 V, ν ₃ = -89 V. The digital receiver (3) is made in the form of a δ / ΡΌΙΡ digital interface converter \ ¥ М8804 manufactured by HUoNyup Mugoeksjoszsk, Great Britain (Yyr: // No.№№ /№о1$5Оит1сго.ТС). Converter (4) is made in the form of a digital-to-analog converter PCM1794A manufactured by Techak ShkjiteSh 1psogrog1ey. USA (those ^^. Y.sot) included according to the well-known scheme of work (Fig. 6). Each of the current amplifiers (5) is made in the form of a 28A5200 bipolar transistor manufactured by TokIa 8etuoyiis1og, Japan (bp: //№№№.5etuoiLo5Yaa.so ..) p / eid). The control input of the amplifier (5) is the base of the transistor, the common output is the emitter, and the power output is the collector. In the manufacture of an audio DAC according to this example, to ensure the greatest balance of quiescent currents (currents in the absence of a signal at the digital input (1)), it is necessary for amplifiers (5) to use transistors with the closest parameters. Transistors are mounted on an individual radiator. This takes into account that the less the device heats up, the more accurate and reliable it works. This is especially true for the mentioned transistors.

Current sensors (8) are made in the form of resistances of the corresponding power dissipation with the smallest possible permissible deviations and / or individually selected close values of electrical resistance. If the current sensors (8) have unequal parameters, then different voltage reference sources (10) should be used for different tracking circuits (9).

Each tracking circuit (9) is made in the form of an operational amplifier (11), in which a non-inverting input through a resistor is connected to the signal input of the tracking circuit (9); an inverting input through a resistor is connected to the reference input of the tracking circuit (9); the output is connected to the control output of the tracking circuit (9);

the output through the capacitor is connected to the inverting input.

The reference voltage source (10) can be made comprising a tuning resistor (12).

The controlled current source (13) is made in the form of an IR transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output.

- 7 025998

The filter (14) is made in the form of a CS filter.

The cascode current follower (15) is made as a composite transistor according to the Shiklai circuit with an η-type field effect transistor (for example, ΙΚΡ240) at the input and four bipolar ρ-η-p transistors connected in parallel. The gate of this composite transistor is the current repeater control input (15), the source is the current repeater power input (15), and the drain is the output. The composite transistor is turned on according to a common-gate circuit, which eliminates the Miller effect in the cascode and increases its linearity and operating frequency.

To significantly increase the sound quality, it is desirable to power the digital part of the audio DAC from an individual battery.

Example 2

To connect a high-impedance load (isostatic speaker system) to the audio DAC, the current repeaters (15) are made in the form of bipolar transistors with an isolated gate (SWT transistors) connected in accordance with a common gate circuit as in example 1.

Description of the operation of the audio DAC according to option 3.

Before starting work, the digital input (1) is connected to the source of the encoded sound information stream, and the analog outputs are connected to the speaker (electrodynamic loudspeaker).

The digital signal from the input (1) through the input pulse transformer (2) is fed to a digital receiver (3), in which it is converted and also digitally supplied to the digital input of the converter (4). The current corresponding to the digital signal passes through the outputs of the converter (4) and the control circuits of the current amplifiers (5).

Reinforced (balanced) currents pass through current repeaters (15) and the winding of the sound transformer (6). Summation of currents occurs directly in the dynamics. The winding of the sound transformer (6) and the speaker simultaneously perform the function of a quantization noise filter. With current balance, the second harmonic is suppressed. This suppression is the greater, the more accurately the balance of quiescent currents is established. Precise balancing is provided by tracking schemes (9). The winding of the sound transformer (6) prevents the appearance of a constant voltage at the speaker terminals in the absence of a signal. Thus, the current-voltage converter is the speaker itself.

Tracking scheme (9) works as follows. If the current gain of the amplifier (5) is somewhat higher, then after turning on the power, the output of the corresponding current sensor (8) will receive a voltage that exceeds the reference voltage supplied by the source (10). At the control output of the tracking circuit (9), the voltage will also increase, which will lead to an increase in voltage at the control input of the current source (13). The latter will lead to an increase in current in the power output of the current source (13). The voltage across the resistor (19) will decrease and will be applied through the filter (14) to the current repeater control input (15). This will lead to a decrease in the voltage at the power input of the current repeater (15), which will lead to a decrease in current through the current amplifier (5). Thus, the calculated value of the amplification is ensured and the current balance through the current amplifiers (5) is maintained.

The implementation of the audio DAC according to option 4.

The inventive audio DAC according to option 4 (Fig. 7) is a simplification of the audio DAC of option 3 and has a digital input (1), which is connected through an input pulse transformer (2) to the input of a digital receiver (3). The input pulse transformer (2) is designed to transmit rectangular pulses of digital data and simultaneously galvanic isolation of the digital input (1) from the remaining elements of the audio DAC.

The output of the digital receiver (3) is connected to the digital input of the converter (4). The digital receiver (3) is designed to receive input data and transfer them to the converter (4), preferably in the format Ι ² δ. The digital receiver (3) and converter (4) are supplied with power from a power source (not shown) connected to the first (16) and second (17) DC power inputs with voltages ν ₁ and ν _2, respectively.

Converter (4) is designed to convert a digital sequence of data about an alternating signal at its digital input into current at its differential output.

One line of the differential current output of the converter (4) is connected through a diode to the first power input (16). Another line of this output of the converter (4) is connected to the control input of the current-controlled current amplifier (5). The common output of the current amplifier (5) is connected to the first power input (16).

The power output of the amplifier (5) is the analog output of the inventive audio DAC.

The audio DAC also contains a controlled current generator (20) connected between the second power input (17) and the analog output of the audio DAC. The current generator (20) represents the load for the current output. If the currents through the current amplifier (5) and the current generator (20) are equal, the common (zero) potential will be set at the analog output.

The current generator (20) is controlled by a tracking circuit (9) through a current source (13). In this case, the analog output is connected to the signal input of the tracking circuit (9), the reference input of which is connected to the common output of the power source. The zero potential tracking circuit (9) is designed to balance currents in the circuits of the current amplifier (5) and current generator (20).

- 8 025998

The control output of the tracking circuit (9) is connected to the control input of a controlled current source (13). The general output of the current source (13) is connected to the third DC power input (18) with a voltage of ν ₃ . The power output of the current source (13) through the filter (14) is connected to the control input of the current generator (20), and through the resistor (19) is connected to the second power input (17).

Examples of specific performance audio DAC option 4.

Example 1

VI = -27 V, ν ₂ = +27 V, ν ₃ = -15 V. The digital receiver (3) is made in the form of an 8 / ΡΌΙΡ digital converter of the HUM8804 interface manufactured by \ Uo1G5op Myugoe1es1goshs5, United Kingdom (1 Шр: / Lu \ y \ y. \ yo1G5OP11nsgo.sot). Converter (4) is made in the form of a digital-to-analog converter PCM1794A manufactured by the company Techa5 1p51gitep15 1psogrogaeb, USA (\ u \\ uu.O.sot). included in a known manner (Fig. 8). The current amplifier (5) is made in the form of a composite transistor according to the Darlington circuit, in which the input bipolar pnp transistor is used to control the conductivity of one or more other pnp transistors connected in parallel (Fig. 8 shows one other transistor in Darlington scheme). The control input of the amplifier (5) is the base of the input transistor, the common output is emitters of other transistors connected through a measuring resistor to the emitter of the input transistor, and the power output is the connected collectors of transistors of the Darlington circuit.

The tracking circuit (9) is made in the form of an operational amplifier (11), in which the non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); an inverting input through a series circuit of two resistors is connected to the signal input of the tracking circuit (9). The connection point of the aforementioned resistors is connected to the reference input via a circuit of parallel connected capacitors and two diodes, one of these diodes being connected to the reference input by the anode and the other by the cathode;

the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input.

The controlled current source (13) is made in the form of a bipolar pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter by a common output.

The filter (14) is made in the form of a capacitor connecting the input and output of the filter with the second power input (17).

The controlled current generator (20) is made in the form of a composite transistor according to the Shiklai circuit with a p-type field effect transistor at the input and two bipolar p-p-p transistors connected in parallel. The gate of this composite transistor is the control input of the current generator (20), the source is connected through a resistor to the second power input (17), and the drain is connected to the analog output of the audio DAC.

Example 2

Performed similarly to example 1, with the exception of the design of a controlled current generator (20), which was changed in order to increase the return of alternating current to the load (a speaker connected to the analog output of the audio DAC) (Fig. 9). The controlled current generator (20) is made in the form of two bipolar transistors connected in parallel, the collectors of which are connected to the second power input (17), and the emitters are connected to the analog output of the audio DAC. The bases of these transistors are connected to the drain of a p-type field effect transistor, the gate of which is the control input of the current generator (20). The source of this field effect transistor is connected to a voltage divider on two resistors connected between the second power input (17) and the analog output of the audio DAC.

Description of the operation of the audio DAC according to option 4.

Before starting work, the digital input (1) is connected to the source of the encoded sound information stream, and the analog output is connected to the speaker (electrodynamic loudspeaker).

The digital signal from the input (1) through the input pulse transformer (2) is fed to a digital receiver (3), in which it is converted and also digitally supplied to the digital input of the converter (4). The current corresponding to the digital signal passes through the outputs of the converter (4) and the control circuit of the current amplifier (5).

If the flowing current from the controlled current generator (20) and the flowing current into the current amplifier (5) is equal, the total (zero) potential is established at the analog output of the audio DAC. The current balance is ensured by the tracking circuit (9), the current source (13) and the current generator (20).

Tracking scheme (9) works as follows. If a positive potential appears at the analog output of the audio DAC, then the voltage at the control output of the tracking circuit (9) will decrease, which will lead to a decrease in the voltage at the control input of the current source (13). The latter will lead to a decrease in the current in the power output of the current source (13). The voltage across the resistor (19) will decrease and will be applied through the filter (14) to the control input of the current generator (20). This will lead to a decrease in the current at the output of the current generator (20), which will lead to a balance of currents and the establishment of a common (zero) potential at the analog output of the audio DAC.

The implementation of the audio DAC option 5.

The inventive audio DAC according to embodiment 5 (Fig. 10) has a digital input (1), which is connected to the input of a digital receiver (3) through an input 0 025998 pulse transformer (2). The input pulse transformer (2) is designed to transmit rectangular pulses of digital data and simultaneously galvanic isolation of the digital input (1) from the remaining elements of the audio DAC.

The output of the digital receiver (3) is connected to the digital input of the converter (4). The digital receiver (3) is designed to receive input data and transfer them to the converter (4), preferably in the format Ι ² δ. The power of the digital receiver (3) and converter (4) is supplied from a power source (not shown) connected to the second (17) DC power input with voltage ν ₂ and a common power input (zero).

Converter (4) is designed to convert a digital sequence of data about an alternating signal at its digital input into current at its differential output.

The differential current output of the converter (4) is connected by each of its two lines to the input of one of the two current repeaters (21). The output of one current repeater (21) through a capacitor (22) is connected to the voltage regulator control input (24) and through a load resistance (23) is connected to the third DC power input (18) with a voltage of ν ₃ . The output of another repeater (21) is connected to the control input of the current-controlled current amplifier (5). The common output of the current amplifier (5) is connected to the first DC power input (16) with voltage VI. The common outputs of the current repeaters (21) are connected to the common input (zero) of the power supply. Current repeaters (21) have low input and high output impedances.

The load resistance (23) simultaneously performs the functions of a current-voltage converter and a volume control. You can use the ladder level control, loudness volume control or a combined passive unit for adjusting the volume and timbre. Perhaps the use of remotely controlled variable resistance - a robot.

The power output of the amplifier (5) is the analog output of the inventive audio DAC and is also connected to the power input of the voltage follower (24). The voltage follower (24) provides amplification of the alternating voltage current. The output of the voltage follower (24) is connected to the second power input (17). At the connection point of the current amplifier (5) and voltage follower (24) there is a low output impedance. This construction of the output stage reduces non-linear distortion, increases the output power and efficiency.

Setting the total voltage (zero) at the analog output of the audio DAC is provided by the tracking circuit (9). In this case, the analog output is connected to the signal input of the tracking circuit (9), the reference input of which is connected to the common output of the power source. The tracking circuit (9) is designed to set the total (zero) potential at the junction point of the current amplifier (5) and voltage follower (24).

The control output of the tracking circuit (9) is connected to the control input of the voltage follower (24).

Examples of specific performance audio DAC option 5.

Example 1

VI = -27 V, ν ₂ = +27 V, ν ₃ = -59 V. The digital receiver (3) is made in the form of a δ / ΡΌΙΡ digital interface converter \ UM8804 manufactured by HUoShop Mutoeuxioszsk, Great Britain (Yyr: // No.№№ /№о1$8 Опш1сго.ТС). Converter (4) is made in the form of a digital-to-analog converter PCM1794A manufactured by Techak 1p51giteSh5 1psogrog1eb. United States (Alhlu.O.sot) included according to the scheme of operation in the ΜΟΝΟ mode for greater current return (Fig. 11). The current repeaters (21) are each made in the form of a bipolar transistor, the collector of which is the output of the current follower (21), the base is the common output, and the emitter is the input of the follower (21). To suppress quantization noise between the output of the current repeater (21) and the load resistance (23), a filter containing a choke and a capacitor is included.

The current amplifier (5) is made in the form of two bipolar transistors connected in parallel. The control input of the amplifier (5) is the connected base of transistors, the common output connected through the measuring resistor of the connected emitters of transistors, and the power output is the connected collectors of transistors.

The tracking circuit (9) is made in the form of an operational amplifier (11), in which the non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); an inverting input through a series circuit of two resistors is connected to the signal input of the tracking circuit (9). The connection point of the aforementioned resistors is connected to the reference input via a circuit of parallel connected capacitors and two diodes, one of these diodes being connected to the reference input by the anode and the other by the cathode;

the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input.

The voltage follower (24) is made in the form of a composite transistor according to the Shiklai circuit with a p-type field effect transistor at the input and two bipolar pp-transistors connected in parallel. The gate of this composite transistor is the voltage follower control input (24), the source is the power follower of the voltage follower (24), and the drain is the output. The composite transistor is turned on by

- 10 025998 scheme with a common shutter, which eliminates the Miller effect in cascode and increases its linearity and operating frequency. This embodiment of the voltage follower (24) has the following advantages: high input impedance, small non-linear distortion, low output impedance.

As a power source used 12 pieces of 12-volt batteries. Each battery has its own charge - discharge controller. In this case, the noise is very small. This configuration is most suitable for creating a control studio audio DAC.

Example 2

Made analogously to example 1, with the exception of the design of the current amplifier (5), which is modified in order to increase the output power (Fig. 12).

The current amplifier (5) is made two-stage complementary. In the first cascade, a bipolar rpn transistor is used, and in the second, two bipolar rpp transistors are connected in parallel. In this case, the emitter of the transistor of the first stage is connected to the first power input through a thermal switch (25). Considering that the transistor collectors of the second stage of the amplifier (5) are connected not to the load, but to the power bus, the amplifier (5) does not have the Miller effect.

Description of the operation of the audio DAC according to option 5.

Before starting work, the digital input (1) is connected to the source of the encoded sound information stream, and the analog output is connected to the speaker (electrodynamic loudspeaker).

The digital signal from the input (1) through the input pulse transformer (2) is fed to a digital receiver (3), in which it is converted and also digitally supplied to the digital input of the converter (4). The current corresponding to the digital signal passes through the outputs of the converter (4) and current repeaters (21).

One current follower (21) creates an alternating voltage of the sound frequency at the load resistance (23). The current of another current repeater (21) enters the control circuit of the current amplifier (5). The current amplified in the amplifier (5) passes through a voltage stabilizer (15).

Tracking scheme (9) works as follows. If a positive potential has appeared at the analog output of the audio DAC, then the voltage will decrease at the control output of the tracking circuit (9) and will be applied to the voltage follower control input (24). This will lead to a decrease in voltage at the power input of the voltage follower (24), that is, to a decrease in voltage at the analog output. As a result, this will lead to the establishment of a common (zero) potential at the analog output.

Industrial applicability

The claimed inventions are implemented using industrially produced devices and materials, can be assembled at any radio engineering enterprise and will find wide application in radio engineering.

Claims (12)

CLAIM 1. A digital-to-analog converter (DAC) comprising a converter (4) with a digital input and a differential current output, characterized in that the current output of the converter (4) is connected by each of its two lines to a control input of one of two current-controlled current amplifiers (5) whose common outputs are connected to the first power input (16), and the power outputs are connected to the ends of the primary winding of at least one sound transformer (6), the middle point of this winding being connected to the second power input (17), while the ends of the secondary winding upo bent transformer (6) are the analog output of the DAC. 2. The digital-to-analog converter according to claim 1, characterized in that its input through the input pulse transformer (2) is connected to the input of the digital receiver (3), the output of which is connected to the digital input of the converter (4), each of the current amplifiers (5 ) is made in the form of a bipolar pnp transistor, the base of which is the control input of the current amplifier (5), the emitter is a common output, and the collector is a power output, while the collectors of these transistors are connected to the ends of the primary windings of two sound transformers (6) , and the midpoint of these windings is connected to the second power input (17), while the ends of the secondary windings of transformers (6) are analog outputs of the DAC, while the DAC is equipped with tuning resistance (7) connected between the bases of the mentioned transistors, the tuning resistance slider (7) is connected to the first power input (16). 3. A digital-to-analog converter, comprising a converter (4) with a digital input and a differential current output, characterized in that the current output of the converter (4) is connected by each of its two lines to a control input of one of two current-controlled current amplifiers (5), common outputs which through the corresponding current sensors (8) are connected to the first power input (16), and the power outputs of which together with the second power input (17) are the analog output of the DAC, while the outputs of the current sensors (8) are connected to the signal inputs of the corresponding tracking circuits (9), the control outputs of which are connected to the control inputs of the respective current amplifiers (5). - 11 025998 4. The digital-to-analog converter according to claim 3, characterized in that its input through an input pulse transformer (2) is connected to the input of a digital receiver (3), the output of which is connected to a digital input of the converter (4), with each of the current amplifiers (5 ) is made in the form of a bipolar pnp transistor, the base of which is the control input of the current amplifier (5), the emitter is a common output, and the collector is a power output, while the collectors of these transistors together with the second power input (17) are an analog output DAC, with each circuit and tracking (9) is in the form of an operational amplifier (11) whose inverting input is connected via a resistor to a signal input tracking circuit (9); a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); the output through the resistor is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to a non-inverting input. 5. A digital-to-analog converter, comprising a converter (4) with a digital input and a differential current output, characterized in that the current output of the converter (4) is connected by each of its two lines to a control input of one of two current-controlled current amplifiers (5), common outputs which through the corresponding current sensors (8) are connected to the first power input (16), and the power outputs are connected to the power inputs of the respective current repeaters (15), the outputs of which are connected to different ends of the sound transformer (6) and are analog by the DAC outputs, the midpoint of the sound transformer (6) is connected to the second power input (17), while the outputs of the current sensors (8) are connected to the signal inputs of the corresponding tracking circuits (9), the control outputs of which are connected to the control inputs of the corresponding controlled current sources (13), the power output of each current source (13) is connected to the control input of the corresponding current follower (15) and through a resistor (19) is connected to the second power input (17). 6. A digital-to-analog converter according to claim 5, characterized in that its input through an input pulse transformer (2) is connected to the input of a digital receiver (3), the output of which is connected to a digital input of the converter (4), with each of the current amplifiers (5 ) is made in the form of a bipolar pnp transistor, the base of which is the control input of the current amplifier (5), the emitter is a common output, and the collector is a power output, with each tracking circuit (9) made in the form of an operational amplifier (11) which has a non-inverting input through a resistor EN with a signal input of the tracking circuit (9); an inverting input through a resistor is connected to the reference input of the tracking circuit (9); the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input; the controlled current source (13) is made in the form of a pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output, with each current repeater (15) made cascode in the form a composite transistor according to Shiklai with a p-type field-effect transistor at the input and several bipolar rp-p transistors connected in parallel, the gate of this composite transistor being the input of the current repeater regulation (15), the source is the power input of the current repeater (15), and the drain - by the output, while the collector of the transistor of each current source (13) is connected to the gate of the current repeater (15) through a CS filter (14). 7. A digital-to-analog converter, comprising a converter (4) with a digital input and a differential current output, characterized in that the current output of the converter (4) is connected by one of its two lines to a control input of a current-controlled current amplifier (5), the common output of which is connected to the first power input (16), and the power output is the analog output of the DAC and is connected to the signal input of the tracking circuit (9), the control output of which is connected to the control input of the controlled current source (13), the power output of which is connected to the input regulation of the controlled current generator (20) and through a resistor (19) is connected to the second power input (17), while the current generator (20) is connected between the second power input (17) and the analog output of the DAC. 8. The digital-to-analog converter according to claim 7, characterized in that its input through the input pulse transformer (2) is connected to the input of the digital receiver (3), the output of which is connected to the digital input of the converter (4), while the current amplifier (5) is made in the form of a composite transistor according to the Darlington circuit, in which the input bipolar pnp transistor is used to control the conductivity of another pnp transistor, the base of the input transistor being the control input of the current amplifier (5), connected emitters of transistors of the Darley circuit gton - with a common output, and connected collectors - with a power output, while the current output of the converter (4) is connected by its own line to the base of the aforementioned input transistor, and the other by its line - through a diode - with the first power input (16), while the tracking circuit (9) is made in the form of an operational amplifier (11), in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); an inverting input through a series circuit of two resistors is connected to the signal input of the tracking circuit (9); the output is connected to the control output of the tracking circuit (9); - 12 025998 output through a capacitor connected to an inverting input; the controlled current source (13) is made in the form of a pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output, while the controlled current generator (20) is made as a composite Shiklai transistor with a p-type field-effect transistor at the input and several bipolar pnp transistors connected in parallel, the gate of the composite transistor of the current generator (20) is the control generator current input (20), the source is connected through the resistor to the second input ohm supply (17), and the drain - with an analog output of the DAC. 9. The digital-to-analog converter according to claim 7, characterized in that its input through the input pulse transformer (2) is connected to the input of the digital receiver (3), the output of which is connected to the digital input of the converter (4), while the current amplifier (5) is made in the form of a composite transistor according to the Darlington circuit, in which the input bipolar pnp transistor is used to control the conductivity of another pnp transistor, the base of the input transistor being the control input of the current amplifier (5), connected emitters of transistors of the Darley circuit gton - with a common output, and connected collectors - with a power output, while the current output of the converter (4) is connected by its own line to the base of the aforementioned input transistor, and the other by its line - through a diode - with the first power input (16), while the tracking circuit (9) is made in the form of an operational amplifier (11), in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); the inverting input through the serial circuit of two resistors is connected to the signal input of the tracking circuit (9), and the connection point of these resistors is connected to the reference input through a circuit of parallel-connected capacitor and two diodes, one of these diodes connected to the reference input by the anode and the other by the cathode ; the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input; the controlled current source (13) is made in the form of a pnp transistor, the base of which is a control input, the collector is a power output, and the resistor connected to the emitter is a common output, while the controlled current generator (20) is made in the form of two parallel-connected bipolar pnp transistors, the collectors of which are connected to the second power input (17), and the emitters to the analog output of the DAC, while the bases of these current generator transistors (20) are connected to the drain of the p-type field effect transistor, the gate of which is the control input the current generator (20), the source of this field-effect transistor is connected to a voltage divider connected between the second power input (17) and the analog output of the DAC. 10. A digital-to-analog converter, comprising a converter (4) with a digital input and a differential current output, characterized in that the current output of the converter (4) is connected by each of its two lines to the input of one of two current repeaters (21), the common terminals of which are connected to a common power input, the output of one current repeater (21) is connected to the voltage regulator control input (24) and through the load resistance (23) is connected to the third power input (18), and the output of another current repeater (21) is connected to the control control input a current amplifier (5), whose common output is connected to the first power input (16), and whose power output is the analog output of the DAC and connected to the power input of the voltage follower (24), the output of which is connected to the second power input (17), in this case, the analog output of the DAC is connected to the signal input of the tracking circuit (9), the reference input of which is connected to a common power output, and the control output of which is connected to the control input of the voltage follower (24). 11. The digital-analog converter according to claim 10, characterized in that its input through the input pulse transformer (2) is connected to the input of the digital receiver (3), the output of which is connected to the digital input of the converter (4), while the current repeaters (21) are made each in the form of a bipolar rpp transistor, the collector of which is the output of the current follower (21), the base is the common output, and the emitter is the input of the follower (21), a filter is connected between the output of the current follower (21) and the load resistance (23) containing throttle and capacitor, while The current (5) is made in the form of parallel-connected bipolar pnp transistors, the control input of the current amplifier (5) is the connected base of transistors, the common output is connected through the resistor, connected emitters of transistors, and the power output is the connected collectors of transistors, while the tracking circuit (9) is made in the form of an operational amplifier (11), in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); the inverting input through the serial circuit of two resistors is connected to the signal input of the tracking circuit (9), and the connection point of these resistors is connected to the reference input through a circuit of parallel-connected capacitor and two diodes, one of these diodes connected to the reference input by the anode and the other by the cathode ; the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input; wherein the voltage follower (24) is made in the form of a composite transistor according to the Shiklai circuit with - 13 025998 by an η-type field-effect transistor at the input and several bipolar RP-transistors connected in parallel, the gate of the composite voltage follower transistor (24) is the voltage follower control input (24), the source is the power follower of the voltage follower (24), and stock - exit. 12. The digital-to-analog converter according to claim 10, characterized in that its input through the input pulse transformer (2) is connected to the input of the digital receiver (3), the output of which is connected to the digital input of the converter (4), while the current repeaters (21) are made each in the form of a bipolar rpp transistor, the collector of which is the output of the current follower (21), the base is the common output, and the emitter is the input of the follower (21), a filter is connected between the output of the current follower (21) and the load resistance (23) containing throttle and capacitor, while The current (5) is made in two stages complementary, in the first stage a bipolar rpn transistor is used, and in the second one there are several bipolar rpp transistors connected in parallel, the base of the transistor of the first cascade is the control input of the current amplifier (5), and power output - connected emitters of transistors of the second stage, while the tracking circuit (9) is made in the form of an operational amplifier (11), in which a non-inverting input through a resistor is connected to the reference input of the tracking circuit (9); the inverting input through the serial circuit of two resistors is connected to the signal input of the tracking circuit (9), and the connection point of these resistors is connected to the reference input through a circuit of parallel-connected capacitor and two diodes, one of these diodes connected to the reference input by the anode and the other by the cathode ; the output is connected to the control output of the tracking circuit (9); the output through the capacitor is connected to the inverting input; in this case, the voltage follower (24) is made in the form of a composite transistor according to the Shiklai circuit with a p-type field effect transistor at the input and several bipolar pp-transistors connected in parallel, the gate of the composite voltage follower transistor (24) is a voltage follower control input (24 ), the source is the power input of the voltage follower (24), and the drain is the output.