Proportional to absolute temperature voltage circuit
First Claim
1. A voltage circuit including a first amplifier having first and second inputs and having an output driving a current mirror circuit, outputs from the current mirror circuit driving first and second n-type bipolar transistors which are coupled to the first and second input of the amplifier respectively, the base of the first n-type transistor being coupled to the second input of the amplifier and the collector of the first transistor being coupled to the first input of the amplifier such that the amplifier keeps the base and collector of the first transistor at the same potential, the second n-type transistor being provided in a diode configuration, and wherein the first and second n-type transistors are adapted to operate at different current densities such that a difference in base emitter voltages between the first and second n-type transistors may be generated across a resistive load coupled to the second n-type transistor, the difference in base emitter voltages being a PTAT voltage, the circuit additionally including first and second p-type bipolar transistors, the first p-type transistor being provided in a feedback configuration between the output node of the amplifier and the inverting input of the amplifier, the second p-type transistor being provided in a diode configuration with the base and collector being commonly coupled via the resistor to the second n-type transistor, the base of the first p-type transistor being coupled to the base of the first n-type transistor and also to the inverting input of the amplifier, the collector of the first p-type transistor being coupled to the collector of the first n-type transistor and also to the non-inverting input of the amplifier, the arrangement of the first p-type and first n-type transistors providing a pre-amplification of the signal prior to the amplification provided by the amplifier.
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Accused Products
Abstract
A voltage circuit including a first amplifier having first and second inputs and having an output driving a current mirror circuit is provided. Outputs from the current mirror circuit drive first and second transistors which are coupled to the first and second input of the amplifier respectively. The base of the first transistor is coupled to the second input of the amplifier and the collector of the first transistor is coupled to the first input of the amplifier such that the amplifier keeps the base and collector of the first transistor at the same potential. The first and second transistors are adapted to operate at different current densities such that a difference in base emitter voltages between the first and second transistors may be generated across a resistive load coupled to the second transistor, the difference in base emitter voltages being a PTAT voltage.
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Citations
38 Claims
- 1. A voltage circuit including a first amplifier having first and second inputs and having an output driving a current mirror circuit, outputs from the current mirror circuit driving first and second n-type bipolar transistors which are coupled to the first and second input of the amplifier respectively, the base of the first n-type transistor being coupled to the second input of the amplifier and the collector of the first transistor being coupled to the first input of the amplifier such that the amplifier keeps the base and collector of the first transistor at the same potential, the second n-type transistor being provided in a diode configuration, and wherein the first and second n-type transistors are adapted to operate at different current densities such that a difference in base emitter voltages between the first and second n-type transistors may be generated across a resistive load coupled to the second n-type transistor, the difference in base emitter voltages being a PTAT voltage, the circuit additionally including first and second p-type bipolar transistors, the first p-type transistor being provided in a feedback configuration between the output node of the amplifier and the inverting input of the amplifier, the second p-type transistor being provided in a diode configuration with the base and collector being commonly coupled via the resistor to the second n-type transistor, the base of the first p-type transistor being coupled to the base of the first n-type transistor and also to the inverting input of the amplifier, the collector of the first p-type transistor being coupled to the collector of the first n-type transistor and also to the non-inverting input of the amplifier, the arrangement of the first p-type and first n-type transistors providing a pre-amplification of the signal prior to the amplification provided by the amplifier.
- 13. A voltage circuit including a first amplifier having first and second inputs and having a first and second transistor coupled to the first and second inputs respectively, the first transistor being additionally coupled to the second input of the amplifier such that the amplifier keeps the base and collector nodes of the first transistor at the same potential, the second transistor being operable at a higher current density to that of the first transistor such that a difference in base emitter voltages between the two transistors may be generated across a load, and wherein the circuit is further configured to include a current mirror circuit provided in a feedback path between the amplifier output and the first and second transistor, the current mirror being adapted to supply a base current for the first and second transistors such that the base collector voltage of each of the transistors is minimized thereby reducing the Early effect, the current mirror circuit including a master and a slave transistor, the master transistor being coupled to the second transistor and the slave transistor being coupled to the first transistor, the slave and first transistor being arranged to form a first stage of an amplifier.
- 25. A bandgap voltage reference circuit comprising a bridge arrangement of transistors including a first and second arm providing first and second inputs to an amplifier which in turn provides a voltage reference as an output, wherein each arm of the bridge includes a transistor, the transistor of the second arm being operable at a higher current density to that of the transistor of the first arm such that a voltage reflective of the difference in base emitter voltages between the first and second transistors is generated across a resistor within a resistor network provided as part of the second arm, and further wherein the first arm is coupled at an intermediate point within the network to the second arm and the bridge is coupled to the voltage reference from the amplifier output such that the amplifier reduces the base collector voltage of the transistor of the first arm, the circuit further including a current mirror circuit, the current mirror circuit including a master and a slave transistor, the master transistor being coupled to the transistor of the second arm and the slave transistor being coupled to the transistor of the first arm, the slave and transistor of the first arm form a first stage of an amplifier.
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37. A bandgap voltage reference circuit including a first amplifier having first and second inputs and providing at its output a voltage reference, the circuit including:
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a first arm coupled to the first input, the first arm having a first and second transistor of the circuit, the bases of each of the first and second transistor being coupled together, the first transistor being additionally coupled to the amplifier output, a second arm coupled to the second input, the second arm having a third and fourth transistor of the circuit and a load resistor, the fourth transistor having an emitter area larger than that of the second transistor, the third transistor being coupled to the amplifier output, and wherein; the load resistor provides, in use, a measure of the difference in base emitter voltages of the second and fourth transistors, Δ
Vbe, for use in the formation of the bandgap reference voltage,the commonly coupled bases of the first and second transistors are additionally coupled to the base of the third transistor and the second input of the amplifier thereby coupling the first and second arms and providing a base current for all three transistors, the amplifier, in use, keeping the base and collector of the first transistor at the same potential.
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38. A method of providing a bandgap reference circuit, the method comprising:
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providing a first amplifier having first and second inputs and generating, in use, at its output a voltage reference, providing a first arm coupled to the first input, the first arm having a first and second transistor of the circuit, the bases of each of the first and second transistors being coupled together, the first transistor being additionally coupled to the amplifier output, providing a second arm coupled to the second input, the second arm having a third and fourth transistor of the circuit and a load resistor, the fourth transistor having an emitter area larger than that of the second transistor, the third transistor being coupled to the amplifier output, such that, in use, the load resistor provides a measure of the difference in base-emitter voltages of the second and fourth transistors, Δ
Vbe, for use in the formation of the bandgap reference voltage, and wherein the commonly coupled bases of the first and second transistors are additionally coupled to the base of the third transistor and the second input of the amplifier thereby coupling the first and second arms and providing a base current for all three transistors, the amplifier, in use, keeping the base and collector of the first transistor at the same potential.
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Specification