JP2638823B2 - Output circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention will be described in the following order.

A Industrial application field B Outline of the invention C Conventional technology (FIGS. 2 and 3) D Problems to be solved by the invention (FIGS. 2 and 3) E Means for solving the problems (FIG. 1) F operation (FIG. 1) G embodiment (FIG. 1) Effect of the invention A Industrial application Field of the Invention The present invention relates to an output circuit, and in particular, sends out a balanced output or an unbalanced output as required. It is something that can be done.

B. Summary of the Invention The present invention simplifies the whole circuit by dividing the output signal of the same phase and the opposite phase with respect to the input signal in the output circuit, and controlling the gain of the amplifier circuit based on the resulting divided voltage. With a simple configuration, a balanced output and an unbalanced output can be stably obtained.

C Prior Art Conventionally, an output circuit capable of outputting a balanced output and an unbalanced output has been proposed as an output circuit for line output of audio equipment and the like (Japanese Patent Application Laid-Open No. 58-121808,
JP-A-59-115604 and JP-A-62-39325).

For example, as shown in FIG. 2, 1 shows an output circuit as a whole, along with providing an input signal S ₁ supplied to the input terminal T1 to the non-inverting input of the operational amplifier 2 having a feedback resistor R1, reversing Operational amplifier circuit 6 via input resistor R2 at input end
To provide the reference voltage output from. This allows the input signal
The output signal obtained at the output terminal in response to the voltage V _I of S ₁ is the resistor R3
And through R4 is grounded, the voltage across the resistor R4 is outputted to the Hotsuto terminal T _H.

Operational amplifier 3 having a feedback resistor R7 has a non-inverting input an input resistor to the terminal R5, the gain consists of the feedback resistor R6 and the operational amplifier circuit 4 to the input voltage V _I through an inverting amplifier circuit 1 In addition to receiving the input voltage having the inverted phase, the inverted input terminal receives the reference voltage output from the operational amplifier circuit 5 via the input resistor R8. Thus the output voltage obtained at the output terminal is grounded via a resistor R9 and R10, the voltage across the resistor R10 is outputted to the cold terminal T _C.

The operational amplifier circuit 5 has a feedback resistor R12, with receiving an input voltage V _I to the non-inverting input receives the output voltage delivered to Hotsuto terminal T _H to the inverting input via an input resistor R11, As a result, a reference voltage determined by the input resistor R11 and the feedback resistor R12 is output. Reference voltage thereby changes depending on the differential voltage between the output voltage of the input voltage V _I and Hotsuto terminal given the operational amplifier circuit 5 is input to the inverting input of the operational amplifier circuit 3 through an input resistor R8.

The operational amplifier 6 contrast, has a feedback resistor R14, and inputs an input voltage of the operational amplifier 3 to a non-inverted input terminal, sent to the cold terminal T _C via an input resistor R13 to the inverting input terminal receiving the output voltage, thereby the operational amplifier reference voltage input resistance which changes in accordance with the difference between the voltage of the output voltage of the input voltage given and the cold terminal T _C in 6 R2
Is input to the inverting input terminal of the operational amplifier circuit 2 via

Thus the output voltage of the operational amplifier circuit 2, the level on the basis of an output voltage output to the cold terminal T _C via the operational amplifier circuit 6 is controlled, the output voltage of the operational amplifier circuit 3 Conversely, the operational amplifier circuit 5, the level of which is controlled based on the output voltage output to the hot terminal.

By insulating the cold terminal T _C and Hotsuto terminal T _H from the ground line (not shown) in accordance connexion balanced output state, Hotsuto terminals T _H, and the cold terminal T _C between the input voltage
Output voltage corresponding to V _I is obtained, which is by being fed back to the operational amplifier 2 and 3 via the operational amplifier circuit 5 and 6, the output voltage of Hotsuto terminals T _H, and the cold terminal T _C are balanced with each other It has been made like that.

On the other hand, in the unbalanced state, the cold terminal T _C
There the output voltage of the cold terminal T _C from being grounded 0
It becomes V, resulting operational amplifier circuit 6 via by operational amplifier circuit 2 output level is controlled to increase the output voltage accompaniment with Hotsuto terminal T _H is increased to this.

Slave In connexion operational amplifier circuit 3, the output voltage of Hotsuto terminal T _H rises, are controlled so that the output level of the operational amplifier circuit 3 via the operational amplifier circuit 5 is reduced, thus the operational amplifier circuit 2, By selecting the values of the input resistances and feedback resistances of 3, 5, and 6 to desired values, the terminal-to-terminal voltage having the same output level as that at the time of unbalance can be obtained even at the time of unbalance.

However, in such an output circuit, it is necessary to provide a large number of operational amplifier circuits, and it is considered that noise is generated accordingly.

In order to equalize the output levels obtained from the hot terminal T _H and the cold terminal T _C during equilibrium and unbalance,
It is necessary to make the resistance values of the resistors R11 and R12 equal to the resistance values of the resistors R13 and R14 to make the gain of the operational amplifier circuits 5 and 6 unity. In this case, the operation of the entire output circuit may become unstable.

Therefore, in practice, the resistance values of the resistors R12 and R14 must be set to values larger than the resistance values of the resistors R11 and R13. As a result, there is a possibility that the output level may change between the equilibrium state and the unbalanced state.

To solve this problem, there is a method using an output circuit as shown in FIG.

That is, reference numeral 10 denotes an output circuit as a whole, and an input voltage applied to the input terminal T2 at the non-inverting input terminal of the operational amplifier circuit 11.
Together give V _I through the resistor R20, providing on the non-inverting input terminal the output voltage of the cold terminal T _C via the resistor R21.

Further, the operational amplifier circuit 11 has a feedback resistor R23, an inverting input terminal is grounded via a resistor R22, and the output voltage is a resistor R24.
It is adapted to be outputted to Hotsuto terminal T _H through.

In the operational amplifier circuit 11 where a value V ₁ of the output voltage of Hotsuto terminal T _H, the voltage at the output terminal of the operational amplifier circuit 11 the value V ₃ Distant, the resistance values of the resistors R20 and R22 values R _a, resistors R21 and values a resistance value of R23 R _b, and the resistance value of the resistor 24 is denoted by the value R _c, the output voltages V _1, the following equation Can be represented by Here Place the non-inverting input voltage value, the following equation to represent the output voltage V ₃ by using the input voltage V ₅ V ₅ And the current flowing through the resistor R20 can be calculated as the value I
Solving for the input voltage V _I at _1, it is possible to obtain the following relational expression _{V 5 = V I -I 1 R} 2 ...... (3). In addition, for the current I _1, placing the output voltage of the cold terminal T _C to a value V _2, the following equation Is established, and by substituting this into equation (3), the following equation is obtained. Can be obtained. Therefore, by substituting equations (5) and (2) into equation (1), the following equation is obtained. Can be obtained, organize this, Can be obtained.

Thus the output voltage V ₂ and the resistor R20~R cold terminal T _C
It is possible to obtain an output voltage V ₁ of the desired output level according to the resistance value of 24.

The operational amplifier circuit 12 with respect to which has a feedback resistor R26, the input voltage V _I is input to the inverting input terminal via the resistor R25. The non-inverting input hand, resistance is grounded via R27, Hotsuto terminals T _H of the output voltage V ₁ is the resistance R2
8 and the resulting output voltage is
It is adapted to be outputted to the cold terminal T _C via 29.

Therefore, for the operational amplifier circuit 12, the voltage at the output
V ₄ , resistors R25 and R27 connected to operational amplifier circuit 11
A value R _a equal to R20 and R22, as well as resistors R26 and R28
_Rb equal to R21 and R23, R29 equal to R24
Letting _Rc be the same as in the case of the operational amplifier circuit 11, corresponding to the equation (1), Can be obtained. Further, when the non-inverting put the voltage value V ₆ the input terminal, in response to (2), the following equation Is obtained. Similarly, the resistance R27 corresponding to the equation (3) is obtained.
And the current flowing through R28 is I ₂ , the following equation is obtained: V ₆ = V _I −R _a I ₂ (10) Can be obtained.

Therefore, substituting equations (9) and (11) into equation (10),
Next formula You can get the relationship and organize this Can be obtained. Therefore, substituting this into equation (8), the following equation Is obtained, and this is organized, Can be obtained.

Thus Hotsuto output voltage V ₁ and the resistors R25~R terminal T _H
It is possible to obtain an output voltage V ₂ of the desired output level according to the resistance value of 29.

Thus, in the time of equilibrium, by cold terminal T _C is isolated from the ground line, it can be in equilibrium from Hotsuto terminals T _H, and the cold terminal T _C obtaining an output voltage V ₁ and the voltage V _2.

During unbalanced hand, by grounding the cold terminal T _C, the output voltage V ₂ becomes 0 [V],
Substituting the value 0 into the output voltage V _{2 of the} equation (7), the following equation is obtained. It is possible to obtain an output voltage V ₁ of the output level represented by the equation.

Therefore, if the resistance value _Ra and the resistance value _Rb are selected to be equal from the equation (7), it is possible to obtain a terminal-to-terminal voltage whose output level does not change at the time of equilibrium and unbalance. Further, by substituting equation (16) into equation (15), the following equation V ₂ = 0 (17) can be obtained, thus preventing the operational amplifier circuit 12 from being overheated. it can.

In this way, an output circuit that can obtain a balanced output and an unbalanced output by the two operational amplifier circuits 11 and 12 can be configured.

D Problem to be solved by the invention However, in the output circuit as shown in FIG.
Respectively based on the output voltage of Hotsuto terminals T _H, and the cold terminal T _C, the operational amplifier circuit 12 and 11 output voltages have been made to control the V ₂ and V ₁ of the, the Hotsuto terminals T _H, and the cold terminal T _C there is a difficult problem to exactly match the level of the output voltage V ₁ and V _2.

In practice, in order to obtain a balanced output, each resistor must be constituted by a variable resistor and adjusted, and therefore, there has been a problem that the entire configuration is complicated.

On the other hand, a method of reducing the resistance values of the resistors R24 and R29 to reduce the variation in practice is conceivable. However, this causes a problem that the operation of the entire output circuit becomes unstable.

The present invention has been made in view of the above points, and has as its object to propose an output circuit capable of stably obtaining a balanced output and an unbalanced output with a simple configuration as a whole.

In the present invention for solving means above problems to solve E problems, non-inverting and amplifying an input signal V _I, which has received the input end the input signal V _I
Relative to the first amplifier circuit 2 for outputting a first output signal V ₁₀ of the same phase, and the inverting amplifier circuit 4 inverts and outputs the input signal V _I, the inverted output from the inverting amplifier circuit 4 inputs receiving a signal V _I to the non-inverting input terminal, the second output signal V ₂₀ of the reverse phase to the input signal V _I amplifies the input signal V _I that the inverted
, A voltage dividing resistor R45 for dividing a potential difference between the output terminals T _H and T _{C of} the first and second output signals V ₁₀ and V _{20, and} a voltage dividing resistor R45. , R46 a divided voltage obtained Te Niyotsu with receiving the inverting input terminal receives the reference voltage to the non-inverting input terminal, an output voltage V ₁₄ corresponding to a difference between the divided voltage and the reference voltage first and The first and second output signals V are output to the inverting input terminals of the second amplifier circuits 2 and 3.
_10, was provided and a third amplification circuit 21 for controlling the signal level of V _20.

F acting dividing resistors R45, the output voltage V ₁₄ corresponding to the difference between the divided voltage and the reference voltage obtained Te R46 Niyotsu to be output to the inverting input of the first and second amplifying circuits 2 and 3 Yotsute than that so as to control the signal levels of the first and second output signals V _10, V _20, in the case of unbalanced output to the grounded output terminal T _C is divided voltage first output since the signal V ₁₀ with the voltage divided as an input signal V _I and phase, as a result, in the first amplifier circuit 2, the first output signal V and the voltage of the same phase are added together to the input signal V _I the resulting increased ₁₀ signal level, whereas, in the second amplifier circuit 3, the input signal V _I inverted
Since anti-phase voltages are added together to be lowered the signal level of the second output signal V _20. Thus, stable operation can be achieved even in the case of an unbalanced output, and a balanced output and an unbalanced output can be stably obtained with a simple configuration.

G Example Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

In Figure 1 where the same reference numerals are assigned to corresponding parts in FIG. 2, 20 as a whole shows an output circuit, the input voltage V _I and the respective non-inverting input terminal of the operational amplifier 2 and the operational amplifier 3 It is designed to receive an input voltage of the opposite phase.

Further, the operational amplifier circuits 2 and 3 each include a feedback resistor R4
Has a 1 and R42, Hotsuto terminal output voltage V ₁₁ and V ₁₂ with receiving the inverting input terminal the output voltage of the operational amplifier circuit 21 via respective input resistors R43 and R44 via a resistor R3 and R9
And to output the T _H and cold terminal T _C.

Hotsuto Between terminals T _H, and the cold terminal T _C, the resistance value is a value R _g
Are connected by voltage dividing resistors R45 and R46.

The operational amplifier circuit 21 has a feedback resistor R47, with receiving a divided voltage of the output voltage V ₁₀ and V ₂₀ obtained via the voltage dividing resistors R45 and R46 to the inverting input, grounding the non-inverting input terminal It has been made like that.

Therefore, in the operational amplifier circuit 21, the output voltage corresponding to the error voltage between the divided voltage and the ground potential is input to the input resistors R43 and R43.
The signal is output to the operational amplifier circuits 2 and 3 via 44.

Accordingly, the resistance value of the resistor R3 is set to the value _Rf , and the operational amplifier circuit 2
If the output voltage of the hot terminal T _H is set to the value V ₁₁ and the output voltage of the hot terminal TH is set to the value V ₁₀ , the following equation is obtained. Can be obtained.

In contrast, the resistance of the resistor R43 value R _d, the resistance value of the resistor R41 at the value R _e, represented an output voltage V ₁₁ using the output voltage V ₁₄ of the input voltage V _I and the operational amplifier circuit 21 If Can be obtained.

In the operational amplifier circuit 21 with respect to this, the output voltage of the cold terminal T _C value V ₂₀ Distant and a feedback resistor R47 is denoted by the value R _h, the following equation In may represent the output voltage V _14.

Therefore, substituting equation (20) into equation (19), Can be obtained, and by substituting this into equation (18), the following equation can be obtained. It is possible to obtain an output voltage V ₁₀ represented by the equation.
Similarly, the resistance value of each of the resistors R9, R42, R44, and R46 is set to a value R equal to the resistance value of each of the resistors R3, R41, R43, and R45.
_f, R _c, R _d, at the R _e, by obtaining the voltage V ₂₀ outputted to the cold terminal T _C, the following equation corresponds to equation (18) And the following equation can be obtained in accordance with equation (19). Can be obtained. Therefore, (2)
0) By substituting the equation, The following equation can be obtained by substituting this into equation (23). Can be in the relationship represents the output voltage V _20.

This makes the hot terminal T _H and the cold terminal T _C
The potential difference V ₀ which the output voltage V ₁₀ and V ₂₀ of the following formula Thus, at the time of equilibrium, the terminal voltage V ₀ expressed by the expression (27) can be obtained.

During unbalanced contrast, since grounding the cold terminal T _C, the divided voltage of 1/2 of the output voltage V ₁₀ of Hotsuto terminals T _H is input to the operational amplifier circuit 21, the divided voltage , The output levels of the operational amplifier circuits 2 and 3 are controlled.

Here, the divided voltage and the input voltage of the operational amplifier circuit 2 have the same phase, whereas the input voltage of the operational amplifier circuit 3 has the opposite phase. Therefore, the divided voltage is changed from 0 [V] to the output voltage V ₁₀
The output level of the operational amplifier circuit 2 can be increased and the output level of the operational amplifier circuit 3 can be decreased by an amount corresponding to a change of 1/2.

That is, in the time of unbalance, by substituting the value 0 to the output voltage V ₂₀ in (22), the following equation Is obtained. Here, assuming that equations (27) and (28) are equal, Is obtained, and this is solved to obtain the following equation Can be obtained.

That is, if the resistance values of the resistors R3, R9, and R41 to R46 are set to values that satisfy the expression (30), it is possible to obtain a terminal-to-terminal voltage having the same output level in the unbalanced state and the balanced state.

Thus, the output circuit can be configured by using only four operational amplifier circuits as a whole, and an output circuit with a simple configuration can be obtained as a whole.

Further dividing the output voltage V ₁₀ and V ₂₀ min, by which is adapted to control the output level of the operational amplifier 2 and 3 on the basis of the divided voltage obtained as a result, to obtain an output circuit that operates stably it can.

According to the above configuration, the output levels of the operational amplifier circuits 2 and 3 that output the positive-phase and reverse-phase output voltages are adjusted by the operational amplifier circuit 21.
By controlling on the basis of the divided voltage of the output voltage V ₁₀ and V ₂₀ through the can with a simple configuration as a whole, to obtain a stable balance and unbalanced output.

H Effect of the Invention As described above, according to the present invention, the output level of the amplifier circuit that outputs the positive-phase and negative-phase output signals is controlled in accordance with the divided voltage of the output signal, so that a simple configuration is achieved. Balanced and unbalanced outputs can be obtained stably.

[Brief description of the drawings]

FIG. 1 is a connection diagram showing an embodiment of an output circuit according to the present invention, and FIGS. 2 and 3 are connection diagrams showing a conventional output circuit. 1, 10, 20 ... output circuit, 2, 3, 4, 5, 6, 11, 1
2, 21 ...... operational amplifier circuit, V _I ...... input voltage, V _1, V _2,
V ₁₀ , V ₂₀ …… Output voltage.

Claims (1)

(57) [Claims] A first amplifier circuit for amplifying an input signal received at a non-inverting input terminal and outputting a first output signal in phase with the input signal; and inverting and outputting the input signal. An inverting amplifier circuit, receiving an inverted input signal output from the inverting amplifier circuit at a non-inverting input terminal, amplifying the inverted input signal, and outputting a second output signal having a phase opposite to the input signal; A second amplifying circuit, a voltage dividing resistor for dividing a potential difference between the output terminals of the first and second output signals, and a divided voltage obtained by the voltage dividing resistor received at an inverting input terminal. Receiving the reference voltage at the non-inverting input terminal and outputting an output voltage corresponding to the difference between the divided voltage and the reference voltage to the inverting input terminals of the first and second amplifier circuits.
A third amplifier circuit for controlling signal levels of the first and second output signals.