JPH065494B2 - DC power supply circuit - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a DC power supply circuit capable of setting a DC output resistance value.

[Prior art]

Conventionally, a DC power supply circuit described below with reference to FIG. 3 has been proposed. That is, it has first, second and third current mirror circuits M1, M2 and M3 having an input end a, an output end b and a common end c common to them. The common end c of the current mirror circuit M1 is connected to the negative end of the DC voltage source E whose positive end is connected to ground, and the input end a is connected to ground via the resistor R. The other end of the load L is connected to the output terminal T to which the other end is connected, and the output end b is connected to the input end a of the current mirror circuit M2. The common end c of the current mirror circuit M2 is connected to the ground, and the output end b is connected to the input end a of the current mirror circuit M3. Further, the common end c of the current mirror circuit M3 is connected to the negative end of the DC voltage source E, and the output end b is connected to the output terminal T. Further, the midpoint of connection between the output end b of the current mirror circuit M2 and the input end a of the current mirror circuit M3, and the DC voltage source E
, And an npn-type transistor Q with its collector at the midpoint of the connection, and the base of the transistor Q is controlled to be off and on when power is supplied and power is not supplied, respectively. One end is connected to the ground and is connected to the constant current source H through the power supply switch S. The above is the configuration of the DC power supply circuit that has been conventionally proposed. According to the DC power feeding circuit having such a configuration, if the power feeding switch S is controlled to be off in the state where the load L is connected to the output terminal T, the DC voltage source E-load L-
The input end a- common terminal c- DC voltage source E of the loop of the output terminal T- resistor R- current mirror circuit M1, a current mirror circuit M1, through its input a, the current I ₁
Corresponding to the DC voltage source E-the common end c of the current mirror circuit M2-the input end a-the current mirror circuit M.
By the loop of the output terminal b of 1-the common terminal c-the DC voltage source E, the current I ₂ flows to the current mirror circuit M1 through the output terminal b thereof, and to the current mirror circuit M2.
Through its input a, the same current I ₂ flows, in response to this, the input terminal a- common terminal c of the common terminal c- output b- current mirror circuit M3 of the DC voltage source E- current mirror circuit M2 Due to the loop of the DC voltage source E, a current I ₃ flows through the current mirror circuit M2 through its output terminal b, and at the same time as the current I ₃ through the input terminal a of the current mirror circuit M3. ₄ flows, and in response thereto, a current I _L is applied to the load L by the loop of the DC voltage source E-the load L-the output terminal T-the output end b of the current mirror circuit M3-the common end c-the DC voltage source E. While flowing, the current I ₅ flows through the output terminal b of the current mirror circuit M3. Therefore, the power supply state of the DC power source to the load L can be obtained. In this case, the voltage of the DC voltage source E is V _E , the voltage of the output terminal T is V _T , the value of the resistor R is r, and the input offset voltage of the current mirror circuit M1 is if V _oF, current _{I 2} flowing through the input terminal a in the current mirror circuit M2 _{is, I 2 = (V T -V} E -V oF) / R (V oF -V E) /
E ……
………… Given in (1). Further, if the mirror ratio of the current mirror circuits M1 and M2 (the ratio of the current flowing through the input end a and the current flowing through the output end b) is 1, and the mirror ratio of the current mirror circuit M3 is m, then The current I ₅ flowing through the output terminal b of the current mirror circuit M3 is I ₅ = m · I ₂ ………………
It is given by (2). Therefore, the current I _L flowing through the load L is I _L = I ₁ + I ₂ = {(m + 1) · (V _OF −V _E )} / r
………… Given in (3). Further, the DC output resistance when the load L side is viewed from the output terminal T at this time is _RT , where R _T = (V _OF −V _E ) / I _L = R / (m + 1).
………… Given in (4). Further, according to the conventional DC power supply circuit shown in FIG. 3, if the power supply switch S is controlled to be ON while the load L is connected to the output terminal T, as described above, As in the case of the power feeding described above, the current I ₁ flows through the current mirror circuit M1 through its input end a, and the current I ₂ flows through the current mirror circuit M1 through its output end b and through the current mirror circuit M2. The same current I ₂ flows through the input end a of the current mirror circuit M3.
, Although current flows I ₃ through the output terminal b, in this case, since the power supply switch S is controlled to be on, the transistor Q1, the current I _H from the constant current source H through the base Flows, and accordingly, the transistor Q1 is turned on. Therefore, the current I ₃ flowing through the output terminal b to the current mirror circuit M2, the collector of the transistor Q1 - flows through the emitter, therefore, the current mirror circuit M3, via the input terminal a, at the time of power supply the same current I ₄ and current I ₃ does not flow, and therefore, the load L, with current I _L does not flow at the time of feeding, the current I ₅ at feeding through its output terminal b to the current mirror circuit M3
Does not flow. Therefore, the non-power supply state of the DC power source to the load L can be obtained. As described above, in the case of the conventional DC power supply circuit shown in FIG. 3, the load L can be DC-powered, and the value R _T of the DC output resistance in this case is given by the equation (4) described above. Therefore, by selecting the mirror ratio m of the current mirror circuit M3 and the value r of the resistor R as desired, the value R _T of the DC output resistance can be appropriately set according to the load L.

[Problems to be Solved by the Invention]

However, in the case of the conventional DC power supply circuit shown in FIG. 3, the current I ₁ flows through the input terminal a of the current mirror circuit M1 even when the DC power supply to the load L is not supplied, Moreover, the same current I ₂ flows through the input terminal a in the current mirror circuit M2 with a current flows I ₂ through an output terminal b to the current mirror circuit M1, further through the output end b in the current mirror circuit M2 with current flow I ₃ Te, its collector to the transistor Q1 - current I ₃ flowing through the emitter, also through the base to the transistor Q1 is a current I _H from the constant current source H flows. Therefore, as a schematic view, P = (I _H + H ₁ + H ₂ + I ₄ ) · | V _E |
........ (5), which has a drawback that the power consumption P is not negligible and is consumed. Therefore, the present invention proposes a novel DC power supply circuit which does not have the above-mentioned drawbacks.

[Means for Solving the Problems]

The DC power supply circuit according to the present invention is similar to the case of the conventional DC power supply circuit described above with reference to FIG. 3, and (b) the first, second and first input terminals, the output terminal and the common terminal common to them. 3 has a current mirror circuit, a common end of the first current mirror circuit is connected to a DC voltage source, an input end is connected via a resistor to an output terminal to which a load is connected, and an output end is The input terminal of the second current mirror circuit is connected, the common terminal of the second current mirror circuit is connected to ground, and the output terminal is connected to the input terminal of the third current mirror circuit; The common end of the current mirror circuit is connected to the DC voltage source, and the output end is connected to the output terminal. However, the direct-current power supply circuit according to the first invention of the present application is the direct-current power supply circuit having the above-described configuration, including: (b) a connection midpoint between the output end of the first current mirror circuit and the resistor; A transistor is connected to the voltage source, and the base of the transistor is connected to the constant current source through a power supply switch that is controlled to be turned off or on depending on whether power is supplied or not supplied. , Has the configuration. Further, a DC power supply circuit according to the second invention of the present application is the same as the above-described configuration of the DC power supply circuit of (A). (C) Between the common end of the first current mirror circuit and the DC voltage source. A transistor is inserted in the connection path, and the base of the transistor is connected to a constant current source through a power supply switch that is controlled to be turned on or off depending on whether power is supplied or not. Have a configuration.

[Action / effect]

According to the DC power supply circuit of the first invention of the present application, when the power supply switch is controlled to be turned off or on so as to turn off the transistor in the state where the load is connected to the output terminal, 1 current mirror circuit,
A current flows through its input end, and in response, a first
Current flows through the output terminal of the current mirror circuit, and the same current flows through the second current mirror circuit through the input terminal of the second current mirror circuit. While the current flows through the output end, the same current flows through the third current mirror circuit through the input end thereof, and accordingly, the current flows through the load and the third current mirror circuit. , Current flows through its output. Therefore, the power supply state of the DC power source to the load can be obtained. In this case, the value of the DC output resistance seen from the output terminal on the load side can be determined by the mirror ratio and the resistance value of the third current mirror circuit, as described above with reference to FIG. Further, according to the DC power supply circuit of the first invention of the present application,
Similarly to the above, if the power supply switch is controlled to be turned on or off so as to turn off the transistor when the load is connected to the output terminal, the transistor is fed with a constant current through its base. The current from the source flows,
In response to this, the transistor is turned on. Therefore, even if a current flows through the output terminal and the resistor to the first current mirror circuit, through the input terminal thereof, the current flows by-passing through the transistor,
Thus, substantially no current flows through the first current mirror circuit through its input end, and thus the second and third current mirror circuits.
The current does not substantially flow in any of the current mirror circuits of the above, and therefore, no current flows in the load. Therefore, the non-power supply state of the DC power supply to the load can be obtained. As described above, also in the case of the DC power supply circuit according to the first invention of the present application, the load can be DC-powered as in the case of the conventional DC power supply circuit described above with reference to FIG.
In this case, the DC output resistance can be set to an appropriate value according to the load by selecting the mirror ratio and the resistance value of the third current mirror circuit as desired. However, in the case of the direct-current power supply circuit according to the first invention of the present application, even when the direct-current power supply to the load is not supplied, even if the current flows through the transistor through the resistor and the current from the constant current source flows through the base of the transistor , The first, second and third current mirror circuits,
Since no current flows, the power consumption is significantly smaller than that of the conventional DC power supply circuit described above with reference to FIG. Further, according to the DC power supply circuit of the second invention of the present application,
With the load connected to the output terminal, if the power supply switch is controlled to turn on or off so as to turn on the transistor, current will flow from the constant current source to the transistor through the base. Flow, and in response, the transistor is on. Therefore, a current flows through the first current mirror circuit through its input end, and in response thereto, a current flows through the first current mirror circuit through its output end and a second current mirror circuit. The same current flows through the circuit through its input end, and in response thereto, a second current mirror circuit flows through its output end with the third current mirror circuit.
The same current flows through the current mirror circuit through the input end thereof, and accordingly, the current flows through the load, and the current flows through the third current mirror circuit through the output end thereof. Therefore, the power supply state of the DC power source to the load can be obtained. In this case, the value of the DC output resistance seen from the output terminal on the load side can be determined by the mirror ratio and the resistance value of the third current mirror circuit, as described above with reference to FIG. Further, according to the DC power supply circuit of the second invention of the present application, the power supply switch is turned off or on so as to turn off the transistor in the state where the load is connected to the output terminal, as described above. If controlled, the transistor is off because no current from the constant current source flows through the base of the transistor. Therefore, even if a current flows through the output terminal and the resistor to the first current mirror circuit through the input terminal thereof, such current does not flow, and thus the second and third current mirror circuits. No current flows in any of the circuits and thus no current flows in the load. Therefore, the non-power supply state of the DC power supply to the load can be obtained. As described above, also in the case of the DC power supply circuit according to the second aspect of the present invention, the load can be DC-powered as in the case of the conventional DC power supply circuit described above with reference to FIG. The DC output resistance can be set to an appropriate value according to the load by selecting the mirror ratio and the resistance value of the third current mirror circuit as desired. However, in the case of the DC power supply circuit according to the second invention of the present application, even if the current from the constant current source flows through the base of the transistor when the DC power supply is not supplied to the load, the first, second, and Since no current flows in any of the current mirror circuits of No. 3, the current consumption is significantly lower than that of the conventional DC power feeding circuit described in FIG.

【Example】

Next, an embodiment of the DC power supply circuit according to the first invention of the present application will be described with reference to FIG. In FIG. 1, parts corresponding to those in FIG. The DC power supply circuit according to the first invention of the present application shown in FIG. 1 has the same configuration as the conventional DC power supply circuit described above with reference to FIG. 3, except for the following matters. That is, the collector of the transistor Q is connected to the midpoint of connection between the output terminal b of the current mirror circuit M2 and the input terminal a of the current mirror circuit M3, but instead of the input terminal a of the current mirror circuit M1 and the resistor R. Of the current mirror circuit M.
The emitter is connected to the DC voltage source E side between the DC voltage source E and the midpoint of the connection between the input terminal a of 1 and the resistor R. The above is the configuration of the embodiment of the DC power supply circuit according to the first invention of the present application. According to the DC power supply circuit of the present invention having such a configuration, when the power supply switch S is controlled to be off in the state where the load L is connected to the output terminal T, the current mirror circuit M1 is A current flows through its input end a, and accordingly, a current flows through the current mirror circuit M1, through its output end b, and at the same time through the current mirror circuit M2 through its input end a. And accordingly, the current mirror circuit M2 outputs to its output end b
Current flows through the current mirror circuit M
3, the same current flows through its input terminal a, and accordingly, the current flows through the load L and the current mirror circuit M3 through its output terminal T. Therefore, the power supply state of the DC power source to the load L can be obtained. In this case, the value of the DC output resistance seen from the output terminal T toward the load L can be determined by the mirror ratio and the value of the resistance R of the third current mirror circuit, as described above with reference to FIG. Further, according to the DC power supply circuit of the first invention of the present application shown in FIG. 1, the load L is applied to the output terminal T in the same manner as described above.
If the power feeding switch S is controlled to be turned on with the transistor Q connected, the current from the constant current source H flows through the base of the transistor Q, and accordingly, the transistor Q is turned on. is doing. Therefore, even if no current flows through the output terminal T and the resistor R to the current mirror circuit M1 through its input end a, the current flows by-pass through the transistor Q, and No current substantially flows through the current mirror circuit M1 through its input terminal a, and accordingly, substantially no current flows through either of the current mirror circuits M2 and M3. , No current flows. Therefore, the non-power supply state of the DC power source to the load L can be obtained. As described above, also in the case of the DC power supply circuit according to the first invention of the present application shown in FIG. 1, the load L can be DC-powered similarly to the case of the conventional DC power supply circuit described in FIG. The DC output resistance in this case can be set to an appropriate value according to the load by selecting the mirror ratio of the current mirror circuit M3 and the value of the resistance R as desired. However, in the case of the DC power supply circuit according to the first invention of the present application shown in FIG. 1, when the DC power supply is not supplied to the load L, current flows through the transistor Q through the resistor R, and also through the base of the transistor Q. Even if the current from the constant current source H flows, the current mirror circuits M1 and M2
Since no current flows in either of M and M3, the power consumption is significantly smaller than that in the case of the conventional DC power supply circuit described in FIG.

Second Embodiment Next, an embodiment of the DC power supply circuit according to the second invention of the present application will be described with reference to FIG. 2, parts corresponding to those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted. The DC power supply circuit according to the second invention of the present application shown in FIG. 2 has the same configuration as the DC power supply circuit according to the present invention described above with reference to FIG. 1 except for the following matters. That is, the transistor Q is the current mirror circuit M1.
Instead of being connected to the midpoint of the connection between the input terminal a and the resistor R, the collector is connected to the common terminal c of the current mirror circuit M1 and the DC voltage source E at the common terminal c of the current mirror circuit M1. It is inserted on the side. Further, the power feeding switch S is replaced with a power feeding switch S'which is controlled to be turned off and on when feeding power and not feeding power, respectively. The above is the configuration of the embodiment of the DC power supply circuit according to the second invention of the present application. According to the DC power feeding circuit of the present invention having such a configuration, when the power feeding switch S ′ is controlled to be ON in the state where the load L is connected to the output terminal T, the transistor Q is connected to the base. A current flows from the constant current source H through the transistor Q, and accordingly, the transistor Q is turned on. Therefore, a current flows through the current mirror circuit M1 through its input end a, and in response thereto, a current flows through the current mirror circuit M1 through its output end b and at the same time, through the current mirror circuit M2. The same current flows through the input end a, and accordingly, the current mirror circuit M2
Current flows through the output terminal b, and the same current flows through the current mirror circuit M3 through the input terminal a, and accordingly, the current flows through the load L and the current mirror circuit. A current flows through M3 through its output b. Therefore, the power supply state of the DC power source to the load L can be obtained. In this case, the value of the DC output resistance seen from the output terminal T toward the load L can be determined by the mirror ratio of the current mirror circuit M3 and the value of the resistor R, as in the case described above with reference to FIG. Further, according to the DC power supply circuit of the second invention of the present application shown in FIG. 2, the load L is applied to the output terminal T in the same manner as described above.
When the power feeding switch S'is controlled to be off in the state where the transistor Q is connected, the current from the constant current source H does not flow to the base of the transistor Q, so that the transistor Q is turned off. Therefore, even if a current flows through the output terminal T and the resistor R to the current mirror circuit M1 through the input terminal a thereof, such current does not flow, and accordingly, the current mirror circuits M2 and M3 have No current flows in either, and thus no current flows in the load. Therefore, the non-power supply state of the DC power source to the load L can be obtained. As described above, also in the case of the DC power supply circuit according to the second invention of the present application shown in FIG. 2, the load L can be DC-powered as in the case of the conventional DC power supply circuit described in FIG. The DC output resistance in this case can be set to an appropriate value according to the load L by selecting the mirror ratio of the current mirror circuit M3 and the values of the resistance R as desired. However, in the case of the DC power supply circuit according to the second invention of the present application shown in FIG. 2, when the DC power supply to the load L is not supplied,
Even if the current from the constant current source H flows through the base of the transistor Q, the current mirror circuits M1 and M2
Since no current flows in both M and M3, the power consumption is significantly smaller than that in the case of the conventional DC power supply circuit described above with reference to FIG. It should be noted that in the above description, 1 is set for each of the DC power supply circuits according to the first invention and the second invention of the present application.
Only one embodiment is shown, for example, the polarity of the DC voltage source E is opposite to that of the above case, and accordingly, the transistor Q is made to be a pnp type, and the same effect as described above is obtained. In addition, various modifications and changes may be made without departing from the spirit of the present invention.

[Brief description of drawings]

FIG. 1 is a connection diagram showing an embodiment of a DC power supply circuit according to the first invention of the present application. FIG. 2 is a connection diagram showing an embodiment of the DC power supply circuit according to the second invention of the present application. FIG. 3 is a connection diagram showing a conventional DC power supply circuit. M1 to M3 ... Current mirror circuit E ... DC voltage source H ... Constant current source L ... Load T ... Output terminal S ... Power supply switch Q ... Transistor

Claims (2)

[Claims] 1. A first, a second and a third current mirror circuit having an input end, an output end and a common end common to them, wherein the common end of the first current mirror circuit is a DC voltage. Connected to the source, the input end is connected via a resistor to the output terminal to which the load is connected, the output end is connected to the input end of the second current mirror circuit, and the common to the second current mirror circuit. The end is connected to the ground, the output is connected to the input of the third current mirror circuit, the common end of the third current mirror circuit is connected to the DC voltage source, and the output is connected to the output terminal. In the connected DC power supply circuit, a transistor is connected between the DC voltage source and the connection midpoint between the output terminal of the first current mirror circuit and the resistor, and the base of the transistor is connected to the power supply. Will it be time DC feed circuit depending on whether made during the feeding through the feeding switch which is controlled to be off or on, characterized in that it is connected to a constant current source. 2. A first, second, and third current mirror circuit having an input end, an output end, and a common end common to them, wherein the common end of the first current mirror circuit is a DC voltage. Connected to the source, the input end is connected via a resistor to the output terminal to which the load is connected, the output end is connected to the input end of the second current mirror circuit, and the common to the second current mirror circuit. The end is connected to the ground, the output is connected to the input of the third current mirror circuit, the common end of the third current mirror circuit is connected to the DC voltage source, and the output is connected to the output terminal. In the connected DC power supply circuit, a transistor is inserted in a connection path between the common end of the first current mirror circuit and the DC voltage source, and the base of the transistor is not supplied with power or not. When power is supplied A DC power supply circuit, characterized in that the DC power supply circuit is connected to a constant current source through a power supply switch that is controlled to be turned on or off in accordance with the condition.