1. Field of the Invention
The present invention relates to a voltage converting device and electronic system thereof, and more particularly, to a voltage converting device having a self-reference feature and realized in a Complementary metal-oxide-semiconductor (CMOS) process and electronic system thereof.
2. Description of the Prior Art
In an integrated circuit, a voltage regulator is a negative feedback circuit for generating an accurate and stable voltage. The voltage outputted by the voltage regulator is utilized as a reference voltage or a supply voltage of other circuits in the integrate circuit, generally. According to different voltage requirements and different features of components of the integrated circuit, the integrated circuit needs multiple voltage regulators to generate different supply voltages.
Please refer to
Generally, the electronic system 10 only has an external system voltage VDDE as the power source. The electronic system 10 needs to use the supply voltage generating unit 100 for generating the supply voltages required by the positive voltage circuit 102, the voltage range converting circuit 104 and the negative voltage circuit 106. Thus, the supply voltage generating unit 100 needs at least four voltage regulators to generate the positive supply voltages VDDP1, VDDP2 and the negative supply voltages VDDN1, VDDN2. When the number of the functions of the electronic systems 10 increases, the number of the voltage regulators needed by the electronic system 10 increases. In other words, the electronic system 10 needs more voltage regulators to provide required supply voltages. However, the voltage regulator needs external inductors or external capacitors, generally, to provide a stable and accurate supply voltage. The manufacture cost of the electronic system 10 significantly increases if the number of voltage regulators arises. Moreover, at the moment the external system voltage VDDE turns on the electronic system 10, time differences are generated between the times of each supply voltage (e.g. the positive supply voltage VDDP1, VDDP2 and the negative supply voltage VDDN1, VDDN2) are generated. The time differences may cause latch-up in the electronic system 10.
On the other hand, since the supply voltages of the electronic system 10 are multiples of the external system voltage VDDE (e.g. the positive supply voltage VDDP1 may be a product of the external system voltage VDDE and 1.5, and the positive supply voltage VDDP2 may be half of the external system voltage VDDE), generally, the supply voltages of the electronic system 10 vary with the external system voltage VDDE, resulting in the supply voltages deviating from the original design values. For example, when the external system voltage VDDE is provided by a battery, the external system voltage VDDE varies with the charge storage level of the battery. The electronic system 10 needs a reference circuit to provide a reference voltage which does not vary with the external system voltage VDDE for stabilizing the supply voltages at the original design values via the feedback mechanism.
Generally, the reference circuit for providing stable reference voltage can be realized by a bandgap circuit consisting of bipolar junction transistors (BJT) realized in CMOS process or CMOS devices. The bandgap circuit realized by the BJT is not sensitive to the process variation, but the BJT of the CMOS process easily encounters latch-up when the power source turns on. Moreover, the component features of the BJT of the CMOS process also cause limitations when designing integrated circuit. Although the bandgap circuit can replace the BJT by the metal-oxide-semiconductor field-effect transistor (MOSFET) operating in sub-threshold zone, the temperature coefficient of the MOSFET operating in sub-threshold zone is easily affected by the process variation, resulting the reference voltage deviates from the design.
Besides, the bandgap circuit only generates a constant reference voltage without the ability of driving loadings. In such a condition, the reference voltage generated by the bandgap circuit needs additional voltage regulators for generating the reference voltages in different voltage levels and having the ability of driving loadings. The manufacturing cost of the electronic system 10 is increased and the design of the electronic system 10 therefore becomes complicated. Thus, how to simplify the circuits for generating the supply voltages in the electronic system becomes an important issue in the industry.
In order to solve the above problems, the present invention provides a voltage converting device having a self-reference feature and capable of generating a supply voltage equipped with the ability of driving loading and not varied with temperature.
The present invention discloses a voltage converting device with a self-reference feature for an electronic system. The voltage converting device comprises a differential current generating module, implemented in a Complementary metal-oxide-semiconductor (CMOS) processing for generating a differential current pair according to a converting voltage; and a voltage converting module, coupled to the differential current generating module, a first supply voltage and a second supply voltage of the electronic system for generating the converting voltage according to the differential current pair, the first supply voltage and the second supply voltage.
The present invention further discloses an electronic system. The electronic system comprises a supply voltage converting module, for generating a first supply voltage and a second supply voltage; at least one voltage converting device with a self-reference feature for an electronic system for generating at least one converting voltage, wherein each voltage converting device comprises: a differential current generating module, implemented in a Complementary metal-oxide-semiconductor (CMOS) processing for generating a differential current pair according to a converting voltage; and a voltage converting module, coupled to the differential current generating module, a first supply voltage and a second supply voltage of the electronic system for generating the converting voltage according to the differential current pair, the first supply voltage and the second supply voltage.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
Please refer to
The differential current generating module 200 comprises a feedback voltage generating unit 204, transistors MN1 and MN2 and resistors R1 and R2. The feedback voltage generating unit 204 comprises resistors R3 and R4, for generating a feedback voltage VFB1 according to a converting voltage VREG1 and a ratio between the resistors R3 and R4. The transistors MN1 and MN2 are NMOS and form a differential pair for generating the differential currents ID1 and ID2. The ratio between the aspect ratios of the transistor MN1 and MN2 is K1 and the transistors MN1 and MN2 operate in the sub-threshold zone. The relationships between the transistors MN1 and MN2 and the resistors R1 and R2 are described as the following. The gates of the transistors MN1 and MN2 are coupled to the feedback voltage VFB1. Two ends of the resistor R1 are coupled to the sources of the transistors MN1 and MN2, respectively, and two ends of the resistor R2 are coupled to the source of the transistors MN2 and the ground GND, respectively. Noticeably, the ends of the resistors R2 and R4 coupled to the ground GND is not limited to be coupled to the ground GND, and can be coupled to other voltages between the supply voltages VDDH and VDDL. Via the feedback path realized by the differential current generating module 200 and voltage converting module 202, the differential current ID1 equals the differential current ID2 when the voltage converting device 20 enters the steady state. Thus, the feedback voltage VFB1 can be expressed as:
V
FB1
=V
GS2+2×ID1×R2 (1)
VGS2 is the voltage difference between the gate and the source of the transistor MN2. Via calculating the current passing through the resistor R1 (i.e. ID1), the formula (1) is modified to be:
The VGS1 is the voltage difference between the gate and the source of the transistor MN1. Since the transistors MN1 and MN2 operate in the sub-threshold zone and the ratio between the resistances of the resistors R2 and R1 is assumed to be L1/2 (i.e.
the formula (2) is modified to be:
V
FB1
=V
GS2
+V
T
×L
1×ln(K1) (3)
VT is the thermal voltage of the transistors MN1 and MN2. Since the voltage VGS2 is inversely proportional to the temperature (i.e. having a negative temperature coefficient) and the thermal voltage VT is proportional to the temperature (i.e. having a positive temperature coefficient), the feedback voltage VFB1 has the feature of not varying with the temperature. According to the ratio between the feedback voltage VFB1 and the converting voltage VREG1, the converting voltage VREG1 can be expressed as:
As a result, the differential current generating module 200 does not require the BJT for generating the converting voltage VREG1 which does not vary with temperature. In other words, the differential current generating module 200 can be realized by CMOS and not limited by the component characteristics of the BJT formed in the CMOS process. According to the formula (4), the converting voltage VREG1 is defined when generating the differential currents ID1 and ID2. That is, the voltage converting device 20 can easily adjust the converting voltage VREG1 via changing the ratios between the resistors R1 and R2 (i.e. L1), the resistors R3 and R4 and the aspect ratios of the transistors MN1 and MN2 (i.e. K1).
Next, the voltage converting module 202 generates the converting voltage VREG1 according to the differential currents ID1 and ID2 and the supply voltages VDDH and VDDL. The supply voltages VDDH and VDDL may be the maximum voltage and the minimum voltage in the electronic system, respectively, and are not limited herein. In this embodiment, the voltage converting module 202 comprises transistors MP1-MP5 and MN3-MN6. The transistors MP1-MP4 and MN3-MN6 form a cascode current mirror to generate an appropriate voltage to the gate of the transistor MP5, for making the transistor MP5 generate the converting voltage VREG1. The operational methods of the cascode current mirror should be well-known to those with ordinary skilled in the art, and are not narrated herein for brevity. Via the feedback path, the converting voltage VREG1 does not vary with the current IREG1 used for driving the post-stage loading. In other words, the current IREG1 passing through the transistor MP5 can be adjusted according to the differential current ID1 and ID2 for driving the loadings of post-stages. Via the feature of the self-reference, the voltage converting device 20 only needs the supply voltages VDDH and VDDL provided by the electronic system to generate the converting voltage VREG1, which does not vary with temperature, as the supply voltage of other circuits in the electronic system.
Please refer to
V
FB2=−(VSG7+2×ID3×R6) (5)
VSG7 is the voltage difference between the source and the gate of the transistor MP7. Via calculating the current passing through the resistor R5 (i.e. ID3), the formula (5) is modified to be:
VSG6 is the voltage difference between the source and the gate of the transistor MP6. Since the transistors MP6 and MP7 operate in the sub-threshold zone and the ratio between the resistances of the resistors R5 and R6 is assumed to be L2/2 (i.e.
the formula (6) is modified to be:
V
FB2=−(VSG7+VT×L2×ln(K2)) (7)
VT is the thermal voltage of the transistors MP6 and MP7. Since the voltage VSG7 is inversely proportional to the temperature (i.e. having a negative temperature coefficient) and the thermal voltage VT is proportional to the temperature (i.e. having a positive temperature coefficient), the feedback voltage VFB2 has the feature of not varying with temperature. According to a ratio between the feedback voltage VFB2 and the converting voltage VREG2, the converting voltage VREG2 can be expressed as:
Accordingly, the differential current generating 300 module does not require the BJT for generating the converting voltage VREG2 which does not vary with temperature. In other words, the differential current generating module 300 can be realized by CMOS and not limited by the component characteristics of the BJT formed in the CMOS process. According to the formula (8), the converting voltage VREG2 is defined when generating the differential currents ID3 and ID4. That is, the voltage converting device 30 can easily adjust the converting voltage VREG2 via changing the ratios between the resistors R5 and R6 (i.e. L2), the resistors R7 and R8 and the aspect ratios of the transistors MP5 and MP6 (i.e. K2).
Next, the voltage converting module 302 generates the converting voltage VREG2 according to the differential currents ID3 and ID4 and the supply voltages VDDH and VDDL. In this embodiment, the voltage converting module 302 comprises transistors MP8-MP11 and MN7-MN11. The transistors MP8-MP11 and MN8-MN10 form a cascode current mirror to generate an appropriate voltage to the gate of the transistor MN11, for making the transistor MN11 generate the converting voltage VREG2. Via the feedback path, the converting voltage VREG2 does not vary with the current IREG2 used for driving the post-stage loading. In other words, the current IREG2 passing through the transistor MN11 can be adjusted according to the differential current ID3 and ID4 for driving the loadings of the post-stages. Comparing to the voltage converting device 20, the direction of the current IREG2 generated by the voltage converting device 30 is different from that of the current IREG1 generated by the voltage converting device 20. Via the feature of self-reference, the voltage converting device 30 only needs the supply voltages VDDH and VDDL provided by the electronic system for generating the converting voltage VREG2, which does not vary with temperature, as the supply voltage of other circuits in the electronic system.
Noticeably, the voltage converting devices of the above embodiments generate the converting voltage having driving ability and not varying with temperature via the feature of self-reference. According to different applications, those with ordinary skill in the art may observe appropriate alternations and modifications. For example, please refer to
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To sum up, the voltage converting devices of the above embodiments have the feature of self-reference and generate the converting voltage not varying with temperature and equipped with a driving ability according to the supply voltages of the electronic system. Accordingly, the number of voltage regulators in the electronic system can be decreased and the latch-up caused by the time differences between the times of different voltage regulators generate the supply voltages can be avoided.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
102128710 | Aug 2013 | TW | national |