JPH0737137Y2 - Constant current generator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a constant current generating circuit capable of obtaining a plurality of temperature-compensated current outputs.

(B) Prior Art Various types of devices have conventionally been proposed for obtaining a temperature-compensated output voltage (current) at the emitter of a transistor, for example, Japanese Utility Model Publication No. 53-33489 is known.
However, the method described in the above publication can only obtain a single output. Therefore, as a circuit for obtaining a plurality of constant voltages (constant currents), Japanese Utility Model Publication No. 62-134116 has been proposed. According to the method described in the publication,
A temperature-compensated output voltage can be obtained by satisfying the conditions of the number of diodes and the resistance ratio.

(C) Problems to be solved by the invention However, if the above method is used to obtain an arbitrary voltage from zero to the power supply voltage, a total of five resistance ratios must be set. There was a problem that it took time.

(D) Means for Solving the Problems The present invention has been made in view of the above points, and includes a first resistor (resistance value R ₁ ) connected to a first reference potential point, and the first resistor. A first diode group consisting of n diodes connected in series with each other, a second diode group consisting of m diodes connected in series with the first diode group, and a second diode group connected to the second diode group. A resistor (a resistance value R ₂ ), a first transistor whose base is connected to a connection midpoint of the first and second diode groups, a third resistor whose one end is connected to an emitter of the first transistor, A second transistor having a base connected to the other end of the third resistor; a third transistor having a base connected to the emitter of the second transistor and a collector connected to the other end of the third resistor;
R ₁ (m−3) = R ₂ (including a fourth resistor connected to the emitter of the transistor and an output transistor having a load at the emitter and having the base to which the emitter voltage of the second transistor is applied. n + 3), the resistance value and the number of diodes are set so that a temperature-compensated constant current is obtained from the collector of the output transistor.

(E) Operation According to the present invention, the current mirror circuit including the third and output transistors is connected to the emitter of the first transistor through the third resistor and the second transistor. Therefore, a temperature-compensated constant current output can be obtained from the collector of the output transistor.

(F) Example FIG. 1 shows an example of the present invention, in which (1) is a resistance value.
The first resistor of R ₁ , (2) is the first of n diodes
Diode group, (3) is a second group consisting of m diodes
A diode group, (4) is a second resistor having a resistance value R ₂ , and (5) is a first transistor whose base is connected to the connection midpoint of the first and second diode groups (2) and (3) , (6) ) Is a _third resistor having a resistance value R ₃ whose one end is connected to the emitter of the first transistor (5), (7) is a second transistor connected to the third resistor (6), and (8) is A third transistor whose base is connected to the emitter of the second transistor (7), (9) is a _fourth resistor having a resistance value R ₄ connected to the emitter of the third transistor (8), and (10) is an emitter. A fifth resistor (11) having a resistance value R ₅ is a first output transistor whose collector is connected to a first load (12), and (13) is a sixth resistor (14) having a resistance value R ₆ is an emitter. It is a second output transistor with the second load (15) connected to the collector.

First, in the figure, the current flowing through the first resistor (1) is I ₁ , the current flowing through the second resistor (4) is I ₂ , the current flowing through the third resistor (6) is I ₃ , and the fourth resistor (9). The flowing current I ₄ , the current flowing through the collector of the first output transistor (10) is I ₅ , the second
The current flowing through the collector of the output transistor (13) is I ₆ . In addition, the base voltage of the first transistor (5) is V ₁ ,
The emitter voltage is V ₂ , the base voltage of the second transistor (7) is V ₃ , the emitter voltage is V ₄ , and the emitter voltage of the third transistor (8) is V ₅ . In the figure, the voltage V ₁
Is V ₁ = mV _BE + I ₂ R ₂ (1) Therefore, the power supply voltage V _cc is V _cc = R ₁ · I ₁ + R ₂ · I ₂ + (m + n) V _BE (2). Here, the first and second diode groups (2) and
Assuming that the characteristics of each diode constituting (3) are uniform, the current I ₁ and the current I ₂ are equal, Becomes Therefore, the voltage V ₁ is And the voltage V ₂ becomes Becomes Then, the voltage V ₃ becomes V ₃ = V ₂ −R ₃ · I ₃ (6), the voltage V ₄ becomes V ₄ = V ₃ −V _BE (7), and the voltage V ₅ becomes V ₅ = V _4- V _BE (8) Here, by substituting the expressions (5) to (7) into the expression (8), the voltage V ₅ becomes And further rearranging equation (9), Becomes Therefore, as is clear from the equation (11), if R ₁ m−R ₂ n−3 (R ₁ + R ₂ ) = 0 (12), the voltage V ₅ is affected by V _BE , that is, the temperature change. Will be unaffected by. Therefore, if the resistance value and the number of diodes are set so that equation (12) holds, the voltage of equation (11)
V ₅ is Becomes Here, by substituting the relationship of the equation (12) into the equation (13), the voltage V ₅ becomes Becomes Where the current I ₄ is Therefore, substituting equation (14) into equation (15), the current I ₄ becomes Becomes Therefore, the current I ₄ can be set to an arbitrary value according to the values of the third resistor R ₃ (6) and the fourth resistor R ₄ (9). Here, the first and second output transistors (10) and (13)
Is connected to the third transistor (8) in a current mirror relationship, so that a current that is not affected by temperature change can flow through the first and second loads (12) and (15). For example, the current I ₅ is And the current I ₆ becomes Becomes

Therefore, as is clear from the equations (17) and (18),
A desired current can be obtained by changing the resistance values R ₅ and R ₆ of the fifth resistor (11) and the sixth resistor (14).

(G) Effect of the Invention As described above, according to the present invention, it is possible to obtain a plurality of temperature-compensated constant currents with a simple design. Further, according to the present invention, there is an advantage that the value of the obtained current can be easily changed only by changing the value of the resistance.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention. (1) ... First resistance, (2) ... First diode group, (3)
... second diode group, (4) ... second resistance, (5) ... first
Transistor, (6) ... Third resistance, (7) ... Second transistor, (8) ... Third transistor, (9) ... Fourth resistance, (10) ... First output transistor.

Claims (1)

[Scope of utility model registration request] 1. A first resistor (resistance value R ₁ ) connected to a first reference potential point, a first diode group composed of n diodes connected in series to the first resistor, and the first resistor group. A second diode group consisting of m diodes connected in series to the diode group, and a second resistor (resistance value R ₂ ) connected to the second diode group
A first transistor having a base connected to a connection midpoint between the first and second diode groups, and a third transistor having one end connected to an emitter of the first transistor
A resistor; a second transistor whose base is connected to the other end of the third resistor; a third transistor whose base is connected to the emitter of the second transistor and whose collector is connected to the other end of the third resistor; A fourth resistor connected to the emitter of the third transistor, and an output transistor having a load on the emitter and having the emitter voltage of the second transistor applied to the base, R ₁ (m-3) A constant current generating circuit, characterized in that the resistance value and the number of diodes are set so that = R ₂ (n + 3), and a temperature-compensated constant current is obtained from the collector of the output transistor.