High tolerance variable gain amplifiers

What is claimed is: 1 . An amplifier comprising: a first operational transconductance amplification (OTA) circuit including a reference signal input section configured to receive a reference voltage to generate an output current based on the reference voltage and a transconductance value of the first OTA circuit, the first OTA circuit further configured to generate a comparison current; a second OTA circuit coupled to the first OTA circuit, the second OTA circuit including an input signal input section configured to receive an input voltage and an output at which an output signal is output, the second OTA circuit having substantially the same transconductance value as the first OTA circuit; and amplifying circuitry having an input coupled to the output of the second OTA circuit, the amplifying circuitry configured to amplify the input voltage to generate and output an output signal. 2 . The amplifier of claim 1 , wherein a feedback path is configured within the first and second OTAs to regulate the transconductance value of the first and second OTA circuits. 3 . The amplifier of claim 1 , wherein the transconductance value of the first and second OTA circuits is regulated to a value determined by a supply voltage applied to the first OTA circuit, the reference voltage and internal resistance of the first OTA circuit. 4 . The amplifier of claim 1 , wherein the output signal of the amplifying circuitry is an output voltage signal that is proportional to a supply voltage applied to the first OTA circuit. 5 . The amplifier of claim 4 , wherein a gain of the output voltage signal is proportional to the supply voltage. 6 . The amplifier of claim 1 , wherein the comparison current is based on a supply voltage applied to the first OTA circuit and internal resistance of the first OTA circuit. 7 . An amplifier comprising: reference signal circuitry including: first and second reference signal transistors, each having first and second current terminals and a control terminal, the control terminals of the first and second reference signal transistors configured to receive a differential reference voltage signal, and the first current terminals of the first and second input transistors coupled to define a first node, and a first tail current transistor having current terminals respectively coupled to the first node and a ground terminal, the reference signal circuitry defining an output current path and a comparison current path; input signal circuitry including: first and second input signal transistors each having first and second current terminals and a control terminal, the control terminals of the first and second input signal transistors configured to receive a differential input voltage signal, and the first current terminals of the first and second input signal transistors coupled to define a second node, and a second tail current transistor having current terminals respectively coupled to the second node and the ground terminal; and amplifying circuitry including: first and second current inputs respectively coupled to the second current terminals of the first and second input signal transistors, and first and second outputs at which a differential output voltage signal is output. 8 . The amplifier of claim 7 , wherein the reference signal circuitry includes a current source structure coupled to the second current terminals of the first and second reference signal transistors. 9 . The amplifier of claim 7 , wherein the first and second nodes, the first and second tail current transistors and the ground terminal form a tail current path. 10 . The amplifier of claim 9 , wherein the tail current path is configured to carry a tail current to regulate a transconductance value of the reference signal circuitry and the input signal circuitry. 11 . The amplifier of claim 9 , wherein the transconductance value is regulated to value determined by a supply voltage applied to the reference signal circuitry, a value of the differential reference voltage signal and internal resistance of the reference signal circuitry. 12 . An amplifier comprising: a first operational transconductance amplification (OTA) circuit configured to receive a reference voltage to generate an output current based on the reference voltage and a transconductance value of the first OTA circuit, the first OTA circuit further configured to generate a comparison current and a first tail current; a second OTA circuit coupled to the first OTA circuit and configured to receive an input voltage and to generate a second tail current, the second OTA circuit having first and second current outputs; and amplifying circuitry having first and second current inputs respectively coupled to the first and second current outputs of the second OTA circuit, and having first and second outputs at which a differential output voltage signal is output. 13 . The amplifier of claim 12 , wherein the first and second tail currents regulate the transconductance value of the second OTA circuit to be approximately the same as the transconductance value of the first OTA circuit. 14 . The amplifier of claim 12 , wherein the amplifying circuitry includes a first output resistor coupled between the first current input and the first output, and a second output resistor coupled between the second current input and the second output. 15 . A method comprising: applying a reference voltage to a first operational transconductance amplifier (OTA) circuit to generate an output current; comparing a current generated in the first OTA circuit from a voltage supply and an internal resistance of the first OTA circuit to the output current; obtaining a transfer gain value of the first OTA circuit and a second OTA circuit coupled to the first OTA circuit; generating tail currents through a first tail current element of the first OTA circuit and through a second tail current element in the second OTA circuit to regulate a transconductance value of the first and second OTA circuits, the second tail current element coupled to the first tail current element to form a tail current feedback path; inputting an input voltage to the second OTA circuit; and generating an output voltage at an output of amplifying circuitry coupled to the second OTA circuit. 16 . The method of claim 15 , wherein the transconductance value of the first and second OTA circuits is regulated to based on a supply voltage applied to the first OTA circuit, the reference voltage and internal resistance of the first OTA circuit. 17 . The method of claim 15 , wherein the output voltage is proportional to a supply voltage applied to the first OTA circuit. 18 . The method of claim 15 , wherein a gain of the amplifying circuitry is relatively constant over a range of process temperature variations. 19 . An amplifier comprising: a first operational transconductance amplification (OTA) circuit including a reference signal input section configured to receive a reference voltage to generate an output current based on the reference voltage and a transconductance value of the first OTA circuit, the first OTA circuit further configured to generate a constant voltage; a second OTA circuit coupled to the first OTA circuit, the second OTA circuit including an input signal input section configured to receive an input voltage and an output at which an output signal is output, the second OTA circuit having substantially the same transconductance value as the first OTA circuit; and amplifying circuitry having an input couple