JP3520128B2 - Programmable DC power supply - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a programmable DC power supply characterized by low noise, and can be used in a VI source or the like incorporated in an IC tester and used in an output voltage. The present invention relates to a programmable DC power supply device capable of performing the change at a high speed. 2. Description of the Related Art In a DC constant-voltage power supply, a large-capacity capacitor is often connected to an output circuit in order to reduce the output impedance and reduce the change in output voltage due to a load change. In this case, if an attempt is made to change the output voltage, a charge / discharge current flows through the capacitor. A normal power supply has a current limiting function for limiting an output current to a certain value or less in order to protect a load circuit or the power supply itself. In general, the current limit value can be changed by a program.Therefore, if the current limit value is set to a small value, the charge / discharge current of the capacitor is limited by the set current limit value. There is a problem that it takes time to charge and discharge the capacitor when changing, and high-speed operation cannot be performed. For example, when the capacitance of the capacitor is 500 μF,
This capacitor is set to 20 V at a current of 10 mA.
It takes about 1 second to charge the battery. In the case of performing automatic measurement, for example, it is necessary to change the voltage in a short time. Therefore, conventionally, when changing the voltage, the current limit value is temporarily set to a large value and then the voltage is changed. After the voltage is stabilized, operations such as changing the setting of the current limit value to a required small value are performed. [0005] This method can attain a prima facie purpose. However, (1) the overcurrent protection for the load does not operate properly during the voltage change, and (2) the current limit value is set. It takes time to add a program to be changed temporarily, and it takes a long time for the circuit to stabilize every time it is changed. (3) Depending on the design, the output may be changed to switch the current range during power supply operation. There are problems such as spikes in voltage. [0006] An object of the present invention is to provide a circuit in which a capacitor is not connected regardless of a set current limit value, even when a large-capacity capacitor is connected to an output circuit, regardless of a response speed at which an output voltage is changed. It is an object of the present invention to provide a programmable DC power supply device that can obtain a response speed equivalent to the above. A programmable DC power supply device according to the present invention is a programmable DC power supply device having a large-capacity capacitor in an output circuit, and outputs the same voltage as the voltage output to the output circuit. A buffer amplifier, a switch for selectively switching and connecting the large-capacity capacitor to the output circuit and the output section of the buffer amplifier, and constantly connecting the capacitor to the output circuit to change the output voltage of the power supply. A control circuit for controlling the operation of the changeover switch so as to temporarily connect to the output portion of the buffer amplifier to charge and discharge the capacitor when the output voltage is changed, and to switch to the output circuit again after completion of the change of the output voltage. It is characterized by having. In the programmable DC power supply having the above-mentioned structure, a large-capacity capacitor is always connected to the output circuit, and when the output voltage of the power supply is changed, the output is temporarily switched to the buffer amplifier output. With this connection, the capacitor is charged and discharged without being restricted by the current limit value, and after the output voltage is stabilized, the connection is switched back to the original output circuit. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the illustrated embodiments. FIG. 1 is a circuit configuration diagram of an embodiment.
Is connected to an output terminal 3 via a current detection circuit 2. The output of the current detection circuit 2 is connected to a contact point a of a buffer amplifier 4 having an amplification factor of 1 and a changeover switch 5 which is preferably an analog switch, and the output of the buffer amplifier 4 is connected to a contact point b of the changeover switch 5. I have. The changeover switch 5 operates according to an instruction from the control circuit 6 and changes the common contact c to the contact a.
Alternatively, a large-capacity capacitor 7 is connected to the common contact c. The output amplifier 1 outputs a voltage corresponding to the programmed output value, the current detection circuit 2 detects a current flowing through the load, and its output is connected to a current limiting circuit (not shown). When the flowing current exceeds the separately set current limit value, the current limiting circuit operates to reduce the input voltage of the output amplifier 1 and control the output current so as not to exceed the current limit value. Buffer amplifier 4 has at least momentarily large current supply capacity, even in a state where a large capacitance of the capacitor is connected as a load, and a buffer amplifying the output V ₀ which the current detection circuit 2, current from a power source V +
Supplying Ic, and outputs the same voltage V _B with this. When the set value of the output voltage is changed, the control circuit 6 receives the information via the input signal line 6a,
A control signal is output via the output line 6b for a certain time from that time, and the control signal is applied to the changeover switch 5 to switch the common contact c from the contact a to the contact b. Next, the circuit operation will be described with reference to FIG. When the voltage setting value is changed from V ₁ to V ₂ at time t _1, the control signal 6b from the control circuit 6, the common contact c of the changeover switch 5 is switched from the contact a to the contact b,
The large capacity capacitor 7 is disconnected from the output circuit and is connected to the output side of the buffer amplifier 4. As a result, the output voltage V _O of the current detection circuit 2 rises at a normal response speed as indicated by the solid line V _O in FIG.
Since the buffer amplifier 4 amplifies degree of 1, it becomes identical to the output V _O output V _B. Note that the buffer amplifier 4 from having a large current supply capacity, by supplying a pulsed charging current as shown as a current I _c, rapidly charges the large-capacity capacitor 7. Note that the dotted line V _O ′ shown in FIG. 2 illustrates a rising state of the output voltage when the charging current of the large-capacity capacitor 7 is limited in the conventional method. [0014] At time t ₂ after a lapse of a predetermined time T, the control signal 6b is returned to the common contact c is the original I switched from the contact b to the contact a state of extinguished changeover switch 5, the large-capacitance capacitor 7 again Connected to the output circuit side. The above description is for the case where the voltage is increased. However, even when the voltage is decreased, the direction of the current flowing through the capacitor 7 is reversed, that is, the operation is the same except that the charge is discharged. It is. Although the generation time T of the control signal is set to a fixed time, it may be configured so that it can be changed according to the voltage step width and / or the current limit value. Further, a circuit for detecting a change in the output voltage V _O is provided, and the generation time T of the control signal 6b is set as a period from when the voltage setting value is changed to when the detection output of the output voltage change detection circuit disappears. Is also good. Further, there are cases where it is not preferable to connect the capacitor 7 to the output circuit, such as when the DC power supply is used in the constant current mode. To address this,
A function of constantly generating a control signal can be added to the control circuit 6, and this mode can be designated to always disconnect the large-capacity capacitor 7 from the output circuit. Although the changeover switch 5 has been described as a single-pole double-throw switch, two single-pole single-throw switches may be used. In this case, a mode in which the large-capacity capacitor 7 is disconnected from both the output circuit and the buffer amplifier circuit 4 can be used. As described above, according to the programmable DC power supply of the present invention, when the output voltage is changed, the large-capacity capacitor connected to the output circuit has a large current supply capability. Since the charge and discharge are performed by the buffer amplifier, the charge and discharge current does not flow in the current detection circuit, and the response of the output voltage can be performed at high speed without being affected by the capacitor.

[Brief description of the drawings] FIG. 1 is a block circuit configuration diagram of an embodiment. FIG. 2 is a time chart showing an operation. [Explanation of symbols] 1 Output amplifier 2 Current detection circuit 3 Output terminal 4 Buffer amplifier 5 Changeover switch 6 control circuit 7 Large capacity capacitors

Claims (1)

(57) [Claim 1] In a programmable DC power supply device having a large capacity capacitor in an output circuit, a buffer amplifier for outputting the same voltage as the voltage output to the output circuit; A changeover switch for selectively connecting and connecting a capacitor to the output circuit and the output section of the buffer amplifier; and normally connecting the capacitor to the output circuit to temporarily change the output voltage of a power supply. A control circuit for controlling the operation of the changeover switch so as to be connected to the output section of the amplifier to charge and discharge the capacitor and to switch over to the output circuit after the change of the output voltage is completed. Programmable DC power supply.