JP2010055490A - Variable output voltage regulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a variable output voltage regulator capable of controlling a regulator IC without being affected by noise and holding supply power voltage to a device within a fixed range. <P>SOLUTION: An output voltage value Vout of a linear regulator IC 21 is divided by feedback circuit resistances R1 and R2 to feedback a voltage value Vfb to the linear regulator IC 21, and a voltage control part 30 is connected between both ends of the feedback circuit resistance R2. The voltage control part 30 includes MOS FETs 31 and 32, an adjusting resistance element R3 and a voltage monitoring circuit 33, and a series circuit of the MOS FET 31 and the adjusting resistance element R3 is connected to the feedback circuit resistance R2 in parallel. The voltage monitoring circuit 33 is arranged in the vicinity of a device to monitor supply voltage to the device, the MOS FETs 32 and 31 are subjected to on/off control in accordance with a monitored voltage value Vdet, and the adjusting resistance element R3 is connected separately from or in parallel with the feedback circuit resistance R2 to adjust the output voltage Vout of the linear regulator IC 21. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a variable output voltage regulator having a function of automatically varying an output voltage of a regulator.

Conventionally, for example, a stabilized power supply circuit such as a switching regulator or a linear regulator has been used for a power supply unit such as a terrestrial wireless relay device (see, for example, Patent Document 1).
The types of regulators are mainly classified into switching regulators and linear regulators. Here, a linear regulator will be described as an example.

  FIG. 3 shows a schematic configuration diagram of the linear regulator. In FIG. 3, 11 is a linear regulator IC, which adjusts the input (Vin) to a DC voltage of a predetermined level and outputs it as Vout. On the output side of the linear regulator IC 11, feedback circuit resistors R1 and R2 are provided in series with the ground. A voltage value Vfb obtained by dividing the output voltage value Vout of the linear regulator IC11 by the feedback circuit resistors R1 and R2 is fed back to the linear regulator IC11. The linear regulator IC 11 compares the feedback voltage value Vfb with the internal reference voltage to adjust the output voltage value Vout. The output voltage value Vout of the linear regulator IC 11 is supplied as an operating power to a device (not shown) disposed at a location away from the linear regulator IC 11.

Since the output voltage value Vout of the linear regulator IC11 is determined by the resistance values of the feedback circuit resistors R1 and R2, the feedback voltage value Vfb divided by the feedback circuit resistors R1 and R2 is matched with the specification value of the linear regulator IC11. This can be expressed as an expression:
Vout = Vfb × (1+ (R1 / R2))
It becomes. Therefore, the output voltage value Vout of the linear regulator IC 11 can be increased if the resistance value of R2 is reduced even if the resistance value of R1 is kept as it is.

  In the above configuration, since the feedback circuit is normally arranged near the linear regulator IC 11, the output voltage value Vout becomes the set voltage value near the output end of the linear regulator IC 11, but is supplied to a device away from the output voltage value Vout. In this case, a voltage drop occurs due to the influence of the substrate pattern and current load, making it difficult to obtain a desired voltage value. If the feedback circuit is arranged away from the linear regulator IC 11, that is, in the vicinity of the device where the voltage drop occurs, the divided voltage value is an analog value and is easily affected by the surroundings, so the linear regulator IC 11. There is a problem of affecting the operation of.

Japanese Patent Laid-Open No. 11-168641

As described above, the switching regulator and the linear regulator adjust the output voltage by comparing the normal output voltage with the reference voltage inside the regulator IC through a feedback circuit such as a resistance voltage divider.
In addition, the power supply pattern on the substrate is ideally a plane, but in practice this is often impossible. In this case, the power supply pattern is made as thick as possible to prevent loss, that is, voltage drop. However, when a device with a large current consumption such as a high-performance FPGA (Field Programmable Gate Array) is adopted, it still cannot cope with it, and there is a case where a recent device whose voltage is lowered cannot meet the specification requirement.

  In order to avoid this, it is conceivable that a feedback circuit is provided not near the regulator IC but in the vicinity of a device for monitoring a remote voltage, or a regulator IC having a remote sensing function for monitoring a remote voltage is used. However, since both are analog signals, if the wiring becomes long, it is affected by ambient noise and affects the operation of the regulator IC itself, so it is difficult to adopt these methods.

  The present invention has been made in order to solve the above-described problems, and enables voltage monitoring at a location away from the output terminal of the regulator, can control the regulator IC without being influenced by ambient noise, and can supply power to the device. An object of the present invention is to provide a variable output voltage regulator capable of maintaining a voltage within a certain range and performing a stable operation.

A variable output voltage regulator according to the present invention includes a regulator IC that outputs a predetermined DC voltage, and an output voltage value of the regulator IC is divided by a feedback circuit resistance and fed back to the regulator IC. A feedback circuit that adjusts a resistance value connected to the feedback circuit resistor, a switching element that controls connection of the adjustment resistor element to the feedback circuit resistor, and an output of the regulator IC A voltage monitoring circuit that is disposed in the vicinity of a device to which a voltage is supplied as an operating power supply and monitors a supply voltage to the device;
The voltage monitoring circuit outputs a monitoring result signal for the device supply voltage as a digital signal, and controls the connection between the feedback circuit resistance and the adjustment resistance element by turning on / off the switching element by the digital signal. The output voltage of the regulator IC is controlled so that the supply voltage to the device is maintained within a predetermined voltage value range.

  According to the present invention, the supply voltage to a device arranged at a location distant from the regulator IC is monitored, and when a voltage drop occurs, the output voltage of the regulator IC is a digital signal that is not easily affected by the surroundings. It is possible to adjust the value, and thus it is possible to stably operate while keeping the power supply voltage supplied to the device within a certain range.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram of a variable output voltage regulator according to an embodiment of the present invention. In FIG. 1, reference numeral 21 denotes a linear regulator IC which adjusts an input (Vin) to a predetermined level of DC voltage and outputs it as Vout.

  On the output side of the linear regulator IC 21, feedback circuit resistors R1 and R2 are provided in series with the ground. A voltage value Vfb obtained by dividing the output voltage value Vout of the linear regulator IC 21 by the feedback circuit resistors R1 and R2 is fed back to the linear regulator IC21. The linear regulator IC 21 compares the feedback voltage value Vfb with an internal reference voltage to adjust the output voltage value Vout. The output voltage value Vout of the linear regulator IC 21 is supplied to a device (not shown) arranged at a location distant from the linear regulator IC 21 as an operation power supply through an output line 22 such as a coaxial cable.

A voltage controller 30 is connected between both ends of the feedback circuit resistor R2 of the linear regulator IC21. The voltage control unit 30 includes switching elements such as N-channel MOS FETs 31 and 32, an adjustment resistance element R 3, and a voltage monitoring circuit 33.
In the MOS FET 31, the drain is connected to the connection point between the feedback circuit resistors R1 and R2, and the source is grounded via the adjusting resistor element R3. In other words, the series circuit of the drain and source of the MOS FET 31 and the adjusting resistor element R3 are connected in parallel to the feedback circuit resistor R2.

  The gate of the MOS FET 31 is connected to the drain of the MOS FET 32 and is connected to a power supply line 35 having a predetermined voltage (direct current) via a bias resistor 34. The source of the MOS FET 32 is grounded, and the control signal output from the voltage monitoring circuit 33 is supplied to the gate via the signal line 36.

  The MOS FETs 31 and 32 and the adjustment resistor element R3 are arranged in the vicinity of the feedback circuit resistance R2 of the linear regulator IC21, and the voltage monitoring circuit 33 is located away from the output terminal of the linear regulator IC21 (where voltage drop is to be monitored). That is, it is arranged in the vicinity of a device (not shown) connected to the output line 22 of the linear regulator IC 21.

  The voltage monitoring circuit 33 is implemented by, for example, a voltage detection IC or a comparator using an operational amplifier, and monitors the voltage supplied to the device. The voltage monitoring circuit 33 outputs an “H” signal to the signal line 36 when the monitoring voltage value Vdet for the device exceeds a preset release threshold voltage, and an inverted signal when the voltage falls below the detection threshold voltage, ie, The “L” signal is output to the signal line 36.

Hereinafter, a specific operation example of the variable output voltage regulator configured as described above will be described with reference to a timing chart shown in FIG.
Here is an example
Output voltage value Vout: 1.2V
Detection threshold voltage: 1.1V
Release threshold voltage: 1.2V
The circuit configuration is such that the output voltage value Vout of the linear regulator IC 21 becomes 1.3 V when the monitored voltage value Vdet falls below 1.1 V.

  As shown in FIG. 2, the voltage monitoring circuit 33 outputs an “H” signal to the signal line 36 when the monitored voltage value Vdet is 1.1 V or more. In a state where the “H” signal is output to the signal line 36, a positive voltage is supplied to the gate of the MOS FET 32, the MOS FET 32 is turned on, and the drain / drain of the MOS FET 32 is supplied from the power supply line 35 through the bias resistor 34. Current flows between the sources. As a result, a voltage drop is caused by the bias resistor 34, the gate potential of the MOS FET 31 is lowered, the MOS FET 31 is turned off, and the adjusting resistor R3 is disconnected from the feedback circuit resistor R2. Therefore, the feedback voltage value Vfb generated at both ends of the feedback circuit resistor R2 is held at a high potential, and the output voltage value Vout of the linear regulator IC 21 is held at 1.2V.

Thereafter, even if the monitored voltage value Vdet decreases, the above state is maintained as long as it is 1.1 V or higher. When the monitored voltage value Vdet falls below 1.1 V at time t1 in FIG. 2, the voltage monitoring circuit 33 outputs an “L” signal to the signal line 36. When the “L” signal is output to the signal line 36, the MOS FET 32 is turned off with the gate potential lowered, and no current flows through the bias resistor 34. As a result, the gate potential of the MOS FET 31 becomes high, the MOS FET 31 is turned on, and the adjustment resistor element R3 is connected in parallel to the feedback circuit resistor R2. The parallel combined resistance value R23 of the feedback circuit resistors R2 and R3 is
R23 = (R2 × R3) / (R2 + R3)
As a result, the feedback voltage value Vfb is decreased below the resistance value of the feedback circuit resistor R2, and the output voltage value Vout of the linear regulator IC 21 is increased to 1.3V.

  Thereafter, when the monitored voltage value Vdet exceeds 1.2 V at time t2 in FIG. 2, the voltage monitoring circuit 33 outputs the “H” signal to the signal line 36 again. Accordingly, as described above, the MOS FET 32 is turned on, and a current flows from the power supply line 35 through the bias resistor 34 between the drain and source of the MOS FET 32. As a result, a voltage drop is caused by the bias resistor 34, the MOS FET 31 is turned off with the gate potential lowered, the adjusting resistor element R3 is disconnected from the feedback circuit resistor R2, and the output voltage value Vout of the linear regulator IC 21 is 1. Return to 2V.

  Similarly, the MOSFETs 31 and 32 are turned on / off according to the monitoring voltage value Vdet of the device monitored by the voltage monitoring circuit 33, and the output voltage value Vout of the linear regulator IC 21 is controlled to supply the voltage to the device. Is maintained in the range of 1.1V to 1.2V.

  According to the above embodiment, the supply voltage to a device arranged at a location distant from the output end of the linear regulator IC can be monitored with a simple configuration with few parts. It is possible to adjust the output voltage value Vout of the linear regulator IC 21 with a digital signal that is not easily affected by the above. As a result, the power supply voltage supplied to the device can be maintained within a certain range, and the device can be operated stably.

  In the above embodiment, when the monitoring voltage value Vdet by the voltage monitoring circuit 33 exceeds the release threshold voltage, the voltage monitoring circuit 33 outputs an “H” signal to the signal line 36 and when the voltage falls below the detection threshold voltage. Although the case where an inverted signal is output is shown, the output signal of the voltage monitoring circuit 33 can be implemented in the same manner even when the sign is reversed from the above description. In that case, the parts type and quantity used in the MOS FETs 31 and 32 are also changed.

  In the above-described embodiment, the case where a MOS FET is used as a switching element that enables / disables the adjusting resistor element R3 of the voltage control unit 30 has been described. However, for example, an equivalent function such as a digital transistor or a photocoupler is provided. Any means can be used as long as it can be realized.

Furthermore, although the case where it implemented to a linear regulator was shown in the said embodiment, it can implement similarly in a switching regulator.
Further, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying constituent elements without departing from the scope of the invention in the implementation stage.

It is a block diagram of the variable output voltage regulator which concerns on one Embodiment of this invention. 3 is a timing chart for explaining the operation of the variable output voltage regulator according to the embodiment. It is a schematic block diagram of the conventional linear regulator.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 21 ... Linear regulator IC, 22 ... Output line, 30 ... Voltage control part, 31 and 32 ... MOS FET, 33 ... Voltage monitoring circuit, 34 ... Bias resistor, 35 ... Power supply line, 36 ... Signal line, R1, R2 ... Feedback Circuit resistance, R3... Resistance element for adjustment.

Claims (1)

A regulator IC that outputs a predetermined DC voltage, a feedback circuit that divides an output voltage value of the regulator IC by a feedback circuit resistance and feeds back to the regulator IC, and adjusts an output voltage value of the regulator IC; and the feedback circuit An adjustment resistor element that is connected to a resistor to adjust a resistance value, a switching element that controls connection of the adjustment resistor element to the feedback circuit resistor, and a device to which an output voltage of the regulator IC is supplied as an operation power supply A voltage monitoring circuit disposed in the vicinity and monitoring a supply voltage to the device;
The voltage monitoring circuit outputs a monitoring result signal for the device supply voltage as a digital signal, and controls the connection between the feedback circuit resistance and the adjustment resistance element by turning on / off the switching element by the digital signal. The output voltage of the regulator IC is controlled so that the supply voltage to the device is maintained within a predetermined voltage value range.

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