Patent Grant
9152157
This application claims the priority benefit of Taiwan application serial no. 100120725, filed on Jun. 14, 2011. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
1. Field of the Invention
The invention relates to a fast response current source. Particularly, the invention relates to a fast response current source capable of dynamically adjusting an output current according to a load demand.
2. Description of Related Art
In a conventional voltage regulator, a feedback circuit is generally used to lock an output voltage to be generated, and a regulation capacitor is disposed at an output terminal of the voltage regulator to assist voltage regulation capability of the voltage regulator. Configuration of the regulation capacitor is mainly to convert pre-stored charges into a driving current for providing to a load when a demand current of the load driven by the voltage regulator is sharply varied, so as to maintain stability of the voltage output from the output terminal of the voltage regulator. In other words, to ensure that the voltage regulator endures a large variation of the demand current of the load, the regulation capacitor of a large size has to be used. Configuration of the large size regulation capacitor increases the cost of the voltage regulator and decreases a response speed of the voltage regulator.
Certainly, in the conventional voltage regulator, a design without using the regulation capacitor is also provided, and such type of the voltage regulator requires a complicated detecting circuit to detect a dynamic variation of the demand current of the load through the output terminal of the voltage regulator, and dynamically adjust the driving current generated by the voltage regulator according to the detected dynamic variation of the demand current of the load. Since such voltage regulator requires the complicated current detecting circuit, the circuit cost is increased and additional current consumption of the current detecting circuit is required.
The disclosure is directed to a fast response current source, which is capable of quickly adjusting a produced output current according to a variation of a demand current of a load.
In one aspect, a fast response current source is provided, including a constant current generating block, a first feedback capacitor, a first current buffer and a first output current generating block. The constant current generating block is coupled to a first feedback terminal for providing a first constant current to flow through the first feedback terminal. The first feedback capacitor is coupled between an output terminal and the first feedback terminal for coupling a voltage variation of the output terminal to the first feedback terminal when a voltage of the output terminal has a rising variation or a falling variation. The first current buffer is coupled to the first feedback terminal for generating a first buffering current to flow through the first feedback terminal, and changing a current value of the first buffering current in response to a corresponding current variation of the first feedback terminal when the voltage at the output terminal has the above variation. The first output current generating block is coupled to the first current buffer for generating a first output current to flow through the output terminal, and changing a current value of the first output current in response to a corresponding variation of the first buffering current when the voltage at the output terminal has the above variation.
According to the above descriptions, the current buffer is used to change the current value of the first buffering current in response to a corresponding current variation of the first feedback terminal when the voltage at the output terminal is varied. Moreover, the first output current generating block is used to quickly adjust the current value of the first output current in response to the current variation of the first buffering current. In this way, when a demand current of the load of the fast response current source is suddenly increased, a sufficient amount of driving current can be provided to satisfy the load demand, and when the demand current of the load is recovered to normal, the increased driving current can be quickly decreased to avoid an overshoot phenomenon of the load.
In order to make the aforementioned and other features and advantages of the invention comprehensible, several exemplary embodiments accompanied with figures are described in detail below.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
Referring to
The fast response current source 100 includes a constant current generating block 110, which is used for providing stable voltages and currents required in operations of the other devices. Moreover, the fast response current source 100 further includes a feedback capacitor C1, a current buffer 130 and an output current generating block 120. In collaboration with the tripartite operations, when a voltage of an output terminal DOT is decreased as the load is dramatically increased, the load current IOUT can be quickly increased.
The constant current generating block 110 is coupled to a feedback terminal FT1 for providing a constant current IR2 to flow through the feedback terminal FT1.
The feedback capacitor C1 is coupled between the output terminal DOT and the feedback terminal FT1. When the voltage of the output terminal DOT has a falling variation, a transient current immediately flows through the feedback capacitor C1 to the output terminal DOT, and a current of the feedback terminal FT1 is transiently increased. In other words, when the voltage of the output terminal DOT has the falling variation, the feedback capacitor C1 couples a voltage variation of the output terminal DOT to the feedback terminal FT1.
The current buffer 130 is coupled to the feedback terminal FT1 and is used for generating a buffering current IR1 to flow through the feedback terminal FT1. When the voltage at the output terminal DOT has the falling variation, in response to a current increase of the feedback terminal FT1, a current value of the buffering current IR1 generated by the current buffer 130 is also increased.
On the other hand, the output current generating block 120 is coupled to the current buffer 130 through a coupling terminal CT1, and generates an output current IM1 according to a voltage of the coupling terminal CT1. When the buffering current IR1 at the feedback terminal FT1 is increased, the voltage level of the coupling terminal CT1 is decreased. Therefore, when the voltage of the output terminal DOT has the falling variation, the output current generating block 120 generates the relatively large output current IM1 in response to the increase of the buffering current IR1. As a result, the load current IOUT can be quickly increased.
According to the above descriptions, when the voltage of the output terminal DOT has the falling variation, a transient current is generated to flow through the feedback capacitor C1. Based on the current buffer 130, the buffering current IR1 flowing through the feedback terminal FT1 is quickly increased, and meanwhile the voltage level at the coupling terminal CT1 is correspondingly decreased. Finally, the current value of the output current IM1 can be quickly increased through the output current generating block 120, so as to further increase the current value of the load current IOUT.
Moreover, the fast response current source 100 can also include a feedback capacitor C2, a current buffer 140 and an output current generating block 150. In collaboration with the tripartite operations, when the voltage of the output terminal DOT is increased as the load is dramatically decreased, the load current IOUT can be quickly decreased.
The feedback capacitor C2 is coupled between the output terminal DOT and a feedback terminal FT2 for coupling a voltage variation of the output terminal DOT to the feedback terminal FT2 when the voltage of the output terminal DOT has a rising variation.
The current buffer 140 is coupled to the feedback terminal FT2, and is used for generating a buffering current IR3 to flow through the feedback terminal FT2. When the voltage at the output terminal DOT has the rising variation, in response to a current increase of the feedback terminal FT2, a current value of the buffering current IR3 generated by the current buffer 140 is also increased.
The output current generating block 150 is coupled to the current buffer 140 through a coupling terminal CT2, and generates an output current IM2 according to a voltage of the coupling terminal CT2. When the buffering current IR3 at the feedback terminal FT2 is increased, the voltage level of the coupling terminal CT2 is accordingly increased. Therefore, when the voltage of the output terminal DOT has the rising variation, the output current generating block 150 generates the relatively large output current IM2 in response to the increase of the buffering current IR3. As a result, the load current IOUT can be quickly decreased.
According to the above descriptions, when the voltage of the output terminal DOT has the rising variation, a transient current is generated to flow through the feedback capacitor C2. Based on the current buffer 140, the buffering current IR3 flowing through the feedback terminal FT2 is quickly increased, and meanwhile the voltage level at the coupling terminal CT2 is correspondingly increased. Finally, the current value of the output current IM2 can be quickly increased through the output current generating block 150, so as to further decrease the current value of the load current IOUT.
An unique feature of the embodiment is that the current buffer 130 is used to sense the current variation of the feedback terminal FT1, and the current buffer 140 is used to sense the current variation of the feedback terminal FT2. A main reason for using the current buffers 130 and 140 to sense the current variations of the feedback terminals FT1 and FT2 is that the current buffer has features of low input impedance, high output impedance and high gain. Therefore, once the voltage at the output terminal DOT is varied, the buffering current IR1 output by the current buffer 130 or the buffering current IR3 output by the current buffer 140 can quickly change with a sufficiently large variation magnitude. Accordingly, the output current IM1 of the output current generating block 120 or the output current IM2 of the output current generating block 150 can quickly change. As a result, the load current IOUT can be quickly changed along with a variation of the load.
It should be noticed that in the fast response current source 100, the feedback capacitor C1, the current buffer 130 and the output current generating block 120 are used to deal with a dramatic increase of the load, and the feedback capacitor C2, the current buffer 140 and the output current generating block 150 are used to deal with a dramatic decrease of the load. However, the invention is not limited thereto, and according to a design requirement, a part of the circuits can be used in collaboration with other output circuit to generate the load current.
Various embodiments are provided below to describe detail structures and operations of various components of the fast response current source 100.
The bias current source generally includes a bias device and a current output device. Preferably, the bias device is coupled to the current output device through the bias terminal BB1, and is coupled to the current buffer 130 through the coupling terminal CT1. The bias device is used for feeding back the voltage at the coupling terminal CT1 to generate a bias voltage at the bias terminal BB1 for providing to an output transistor MP22. Then, the current output device generates the output current IM1 to flow through the output terminal DOT according to the bias voltage at the bias terminal BB1.
In detail, the bias device is, for example, composed of a bias transistor MP21, and the current output device is composed of the output transistor MP22, though the invention is not limited thereto. A gate of the output transistor MP22 is coupled to the bias terminal BB1, the source/drain thereof is coupled to a voltage source terminal VDDT for receiving a voltage source VDD, and the drain/source thereof is coupled to the output terminal DOT. Moreover, a gate of the bias transistor MP21 is coupled to the bias terminal BB1, a source/drain thereof is coupled to the voltage source terminal VDDT, and the drain/source thereof is coupled to the coupling terminal CT1. Under such configuration, once the voltage at the output terminal DOT is decreased to decrease the voltage level of the coupling terminal CT1, the output current generating block 120 can generate the relatively large output current IM1.
It should be noticed that a resistor device RD1 can be coupled in series on a coupling path of the transistor MP21 and the bias terminal BB1. The resistor device RD1 can prevent an instant change of a voltage at the gate of the bias transistor MP21 along with a variation of the voltage at the coupling terminal CT1 to cause that the bias transistor MP21 increases the generated current to charge the gate of the transistor MP22 to suppress the capability that the transistor MP22 provides the output current IM1.
Moreover,
The bias transistor MN22 is used for constructing a bias device in the bias current source. A gate of the bias transistor MN22 is coupled to a bias terminal BB2, a source/drain thereof is coupled to a voltage source terminal GNDT for receiving a voltage source GND, and the drain/source thereof is coupled to the coupling terminal CT2. The bias terminal BB2 is further coupled to the coupling terminal CT2. The transistor MN21 is an output transistor, and a gate thereof is coupled to the bias terminal BB2, a source/drain thereof is coupled to the voltage source terminal GNDT, and the drain/source thereof is coupled to the output terminal DOT. Under such configuration, once the voltage at the output terminal DOT is increased to increase the voltage level of the coupling terminal CT2, the output current generating block 150 can generate the relatively large output current IM2.
Moreover, a resistor device RD2 is coupled in series on a coupling path of the bias transistor MN22 and the bias terminal BB2. The resistor device RD2 can prevent an instant change of a voltage at the gate of the bias transistor MN22 along with a variation of the voltage at the coupling terminal CT2 causing the bias transistor MN22 to increase the generated current to charge the gate of the output transistor MN21 and thereby suppress the capability of providing the output current IM2 by the output transistor MN21.
On the other hand,
The reference current source 111 may include current sources IBIAS1 and IBIAS2, where the current source IBIAS1 generates the reference current IB1 and provides the reference current IB1 to the transistors MN11 and MN12, and the current source IBIAS2 generates the reference current IB2 and provides the reference current IB2 to the transistor MN13.
Moreover, the constant current generating block 110 is further coupled to a feedback terminal FT2, and provides a constant current I0 to flow through the feedback terminal FT2. The constant current I0 is, for example, provided by a current mirror 112 constructed by the current source I1 and transistors MP11 and MP12.
The constant current generating block 210 includes a reference current source 211 and a current mirror 213 formed by transistors MN11, MN12, MN13, MN14 and MNB3. An operation method of the constant current generating block 210 is similar as that described in the aforementioned embodiment, which is not repeated herein for simplicity's sake.
Similar to the fast response current source 100, in collaboration with the operations of the feedback capacitor C1, the current buffer 230 and the output current generating block 220, when the voltage of the output terminal DOT is decreased as the load is dramatically increased, the load current IOUT is quickly increased.
In detail, the feedback capacitor C1 is coupled between the output terminal DOT and the feedback terminal FT1, and when the voltage at the output terminal DOT has the falling variation, the voltage variation of the output terminal DOT can be coupled to the feedback terminal FT1 through the feedback capacitor C1. The current buffer 230 is coupled between the coupling terminal CT1 and the feedback terminal FT1. The current buffer 230 is used to generate the buffering current IR1, and changes a current value of the buffering current IR1 in response to the corresponding current variation of the feedback terminal FT1 when the voltage at the output terminal DOT has the falling variation. Moreover, the output current generating block 220 is further coupled to the current buffer 230 through the current buffer 240, and changes a current value of the output current IM1 in response to a corresponding variation of the buffering current IR1 when the voltage at the output terminal DOT is varied.
On the other hand, in collaboration with the operations of the feedback capacitor C2, the current buffer 240 and the output current generating block 220, when the voltage of the output terminal DOT is increased as the load is dramatically decreased, the load current IOUT is quickly decreased.
In detail, the feedback capacitor C2 is coupled between the output terminal DOT and the feedback terminal FT2, and when the voltage at the output terminal DOT has the rising variation, the voltage variation of the output terminal DOT can be coupled to the feedback terminal FT2 through the feedback capacitor C2.
The current buffer 240 is coupled between the feedback terminal FT2 and the current buffer 230. The current buffer 240 is used to generate the buffering current IR2 to flow through the feedback terminal FT2, and changes a current value of the buffering current IR2 in response to the corresponding current variation of the feedback terminal FT2 when the voltage at the output terminal DOT has the rising variation. Moreover, the output current generating block 220 is further coupled to the current buffer 240, and changes a current value of the output current IM1 in response to a corresponding variation of the buffering current IR2 when the voltage at the output terminal DOT is varied.
In the present embodiment, the current buffers 230 and 240 are respectively constructed by buffer transistors MNB1 and MPB1, though the invention is not limited thereto. A gate of the buffer transistor MNB2 is coupled to the regulation terminal BT1 in the constant current generating block 210, a source/drain thereof is coupled to the feedback terminal FT1, and the drain/source thereof is coupled to the output current generating block 220. Under such a configuration, once the voltage at the output terminal DOT is decreased to decrease the voltage at the feedback terminal FT1, the buffering current IR1 output by the transistor MNB2 is correspondingly increased. A gate of the buffer transistor MPB1 is coupled to the regulation terminal BT2 in the constant current generating block 210, a source/drain thereof is coupled to the feedback terminal FT2, and the drain/source thereof is coupled to the output current generating block 220. Under such configuration, once the voltage at the output terminal DOT is increased to increase the voltage at the feedback terminal FT2, the buffering current IR2 output by the transistor MPB2 is correspondingly increased.
Moreover, a resistor device RD1 is coupled in series between the current output device and the bias device. In detail, the resistor device RD1 is coupled in series between the gate of the bias transistor MP51 and the bias terminal BB1. The resistor device RD1 can prevent a change of a voltage at the gate of the bias transistor MP51 to cause the bias transistor MP51 to increase the generated current to charge the gate of the output transistor MP52 and thereby suppress the capability of providing the output current IM1 by the transistor MP52.
Referring to
A control terminal (a gate) of the driving transistor DM1 is coupled to an output terminal of the operational amplifier OPAMP1, and one terminal of the driving transistor DM1 is coupled to a power voltage VDD, and another terminal thereof is coupled to a voltage dividing circuit 310.
The voltage dividing circuit 310 is coupled between a driving output terminal DOT of the voltage regulator 300 and the operational amplifier OPAMP1. The voltage dividing circuit 310 is used to divide a voltage at the driving output terminal DOT to generate the feedback voltage VFB.
The voltage dividing circuit 310 may include resistors R1 and R2 coupled in series, and is used to divide the voltage at the driving output terminal DOT to generate the feedback voltage VFB.
It should be noticed that the fast response current source 320 is coupled across two terminals (the terminal coupled to the voltage source VDD and the terminal coupled to the voltage dividing circuit 310) of the driving transistor DM1. The fast response current source 320 can be implemented by one of the fast response current sources 100 and 200 of the invention to produce the load current IOUT required to be generated by the voltage regulator 300. Operation details of the fast response current sources 100 and 200 have been described in detail in the embodiments of
In summary, by constructing the feedback capacitor at the output terminal of the fast response current source, the voltage variation of the load at the output terminal caused by the current demand variation can be fed back, and the current buffer performs a charging or discharging operation corresponding to an instantaneous increase or decrease of the demand current of the load. In this way, the fast response current source can dynamically increase or suppress the output current according to the current demand of the load, so as to quickly and stably satisfy the demand of the load.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
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