Positive temperature coefficient bias compensation circuit

What is claimed is: 1. A radio frequency amplifier including: (a) one or more amplifier stages, each having a corresponding bias input; (b) one or more bias circuits, each configured to be coupled in series between a power supply voltage and a bias input of a corresponding amplifier stage, for providing a bias current to the corresponding amplifier stage; and (c) at least one bias compensation circuit, each bias compensation circuit having an input configured to be coupled to the power supply voltage and an output configured to be coupled to the bias input of at least one of the one or more amplifier stages, the at least one bias compensation circuit being in parallel electrically with at least one of the bias circuits between the power supply voltage and the bias input of at least one of the one or more amplifier stages, the at least one bias compensation circuit and including a positive temperature coefficient (PTC) device coupled in series between the input of the bias compensation circuit and the output of the bias compensation circuit, the PTC device being positioned at a distance d 1 from a specific one of the one or more amplifier stages and outputting a compensation current that is a function of the temperature of the PTC device. 2. A radio frequency amplifier including: (a) one or more amplifier stages each having a corresponding bias input; (b) one or more bias circuits, each configured to be coupled in series between a power supply voltage and a bias input of a corresponding one of the one or more amplifier stages and configured to output a bias current to the corresponding one amplifier stage; and (c) at least one bias compensation circuit, each bias compensation circuit having an input configured to be coupled to the power supply voltage and an output configured to be coupled to the bias input of at least one of the one or more amplifier stages, the at least one bias compensation circuit being in parallel electrically with at least one of the bias circuits between the power supply voltage and the bias input of at least one of the one or more amplifier stages, the at least one bias compensation circuit including a positive temperature coefficient (PTC) device coupled in series between the input of the bias compensation circuit and the output of the bias compensation circuit, the PTC device being positioned at a distance d 1 from a specific one of the one or more amplifier stages and outputting a compensation current that is a function of the temperature of the PTC device; wherein each bias circuit coupled in parallel electrically with a specific one of the at least one bias compensation circuits is positioned at a distance of at least d 2 from all amplifier stages, and d 1 <d 2 . 3. The invention of claim 1 or 2 , wherein the compensation current from each bias compensation circuit supplements the bias current output by the bias circuits coupled in parallel electrically to such bias compensation circuit as a function of the temperature of the PTC device of such bias compensation circuit relative to the temperature of the bias circuits. 4. The invention of claim 1 or 2 , wherein the PTC device of at least one bias compensation circuit is adjacent the specific one amplifier stage. 5. The invention of claim 1 or 2 , wherein the specific one amplifier stage from which the PTC device of at least one bias compensation circuit is positioned at a distance d 1 generates a greater amount of heat during operation compared to a second amplifier stage. 6. The invention of claim 5 , wherein the bias circuit coupled to the bias input of the second amplifier stage is coupled in parallel electrically with at least one bias compensation circuit having a PTC device positioned at a distance d 1 from the specific one amplifier stage generating a greater amount of heat during operation compared to the second amplifier stage. 7. The invention of claim 1 or 2 , wherein each bias circuit coupled in parallel electrically with one of the at least one bias compensation circuits is positioned farther from every amplifier stage than is the PTC device of such coupled bias compensation circuits. 8. The invention of claim 1 or 2 , further including a resistor series coupled between the PTC device and the output of the bias compensation circuit, for regulating the compensation current. 9. The invention of claim 8 , wherein the resistor is settable or variable. 10. The invention of claim 1 or 2 , wherein the compensation current output by a specific one of the at least one bias compensation circuits offsets Gain droop of the amplifier stages coupled to the bias circuits coupled in parallel electrically with the specific one bias compensation circuit. 11. The invention of claim 1 or 2 , wherein the PTC device is a PTC transistor or a diode. 12. The invention of claim 1 or 2 , wherein the PTC device increases the output compensation current when the temperature of the PTC device is increased. 13. The invention of claim 2 , wherein the one or more amplifier stages, the one or more bias circuits, and the at least one bias compensation circuit are all implemented on an integrated circuit die, and the distances d 1 and d 2 are distances on the integrated circuit die. 14. A radio frequency amplifier including: (a) one or more amplifier stages; (b) one or more bias circuits, each coupled to a corresponding one of the one or more amplifier stages and configured to output a corresponding bias current to the corresponding one amplifier stage; and (c) at least one bias compensation circuit, each bias compensation circuit having an output coupled in parallel with the output of at least one of the bias circuits and including a positive temperature coefficient (PTC) device configured to be coupled to a power supply voltage and being coupled to the output of the bias compensation circuit, the PTC device being positioned at a distance d 1 from a specific one of the one or more amplifier stages and outputting a compensation current through the resistor that is a function of the temperature of the PTC device; wherein each bias circuit coupled to a specific one of the at least one bias compensation circuits is positioned at a distance of at least d 2 from all amplifier stages, and d 1 <d 2 ; further including a compensation circuit configured to monitor a target circuit having one or more performance parameters affected by self-heating during operation of the target circuit, wherein the compensation circuit is configured to be coupled to and adjust one or more circuit parameters of the target circuit sufficient to substantially offset the effect of self-heating during operation of the target circuit on the one or more performance parameters, the compensation circuit including: (a) at least one sensor located with respect to the target circuit so as to measure the temperature T of the target circuit and generate an output signal representing such temperature T; (b) at least one tracking circuit, each coupled to at least one sensor, configured to capture a temperature T(t=t 0 ) at a time t 0 after the commencement of operation of the target circuit, and to sample a temperature T(t>t 0 ) at times after time to and during operation of the target circuit, the at least one tracking circuit including: (1) a differential amplifier having a first input coupled to the output signal of a corresponding sensor, a second input, and an output representing the difference between signals applied to the first input and the second input; and (2) a storage capacitor coupled to the second input of the differential amplifier and selectively coupled to the d