Microfabricated calorimeter for RF power measurement

What is claimed is: 1. A radio frequency (RF) power calorimeter comprising: a load electrically coupled to a RF input, the RF input configured to be electrically coupled to an RF power source; a variable low-frequency power source electrically coupled to the load and configured to apply low-frequency power to the load; a thermal medium thermally coupled to the load; an outlet temperature sensor thermally coupled to the thermal medium, the outlet temperature sensor being positioned to measure the temperature of the thermal medium due to heating by the load; circuitry configured to calculate power of the RF source electrically coupled to the RF input by: determining an average power of the RF source based on temperature measurements of the thermal medium using a variable bias from the low-frequency power source; a single fluid loop comprising a fluid channel path array configured to vary a flowrate of said thermal medium through said single fluid loop. 2. An RF power calorimeter of claim 1 , wherein said thermal medium is a fluid circulated through said thermal medium loop and said flowrate of said thermal medium fluid through said thermal medium loop is variable. 3. The RF power calorimeter of claim 1 , wherein said fluid channel path array is comprised of a fluid switch in fluid communication with multiple fluid channels, each fluid channel of said fluid channel path array having a different length and/or hydraulic diameter, and each fluid channel of said fluid channel path array has a thermal medium pump. 4. The RF power calorimeter of claim 3 , wherein determining an average power of the RF source includes: applying a known low-frequency input to the load, the known low-frequency input having a predetermined power value; measuring a first output temperature of the thermal medium after application of the low-frequency input to the load; applying the RF source to the load during application of the known low-frequency input; measuring a second output temperature of the thermal medium during application of the known low-frequency input and the RF source; reducing the power value of the known low-frequency input while measuring the output temperature of the thermal medium until the output temperature is substantially equal to the first output temperature; determining a power value of the known low-frequency input when the output temperature is substantially equal to the first output temperature; and calculating power of the RF source based on the difference between the predetermined value of the known low-frequency input and the power value of the known low-frequency input when the output temperature is substantially equal to the first output temperature. 5. An RF power calorimeter as set forth in claim 4 , wherein said variable low-frequency power source is an alternating current voltage source or a direct current voltage source. 6. An RF power calorimeter as set forth in claim 5 , wherein said thermal medium is a substrate thermally coupled to a heat exchanger, said outlet temperature sensor is a Wheatstone bridge, said power calorimeter is configured to measure power between about 100 .mu.W and 100 mW, and said power calorimeter is configured to measure power at frequencies down to 0 Hz and well above 12 GHz. 7. An RF power calorimeter as set forth in claim 6 , wherein said RF power calorimeter is further comprised of a non-conductive substrate; wherein said load and output sensor are microfabricated on said non-conductive substrate. 8. An RF power calorimeter comprised of a microfabricated calorimeter having a thermal medium and a low frequency power source; said power calorimeter is configured to determine an average power of an RF source based on temperature measurements of said thermal medium using a variable bias from the low-frequency power source; a single fluid loop comprising a fluid channel path array configured to vary a flowrate of said thermal medium through said single fluid loop. 9. A method of measuring radio frequency (RF) power, the method comprising: providing a load electrically coupled to a RF input; providing a thermal medium thermally coupled to the load; applying a known low-frequency input to the load, the known low-frequency input having a predetermined power value; measuring a first output temperature of the thermal medium after application of the known low-frequency input to the load; applying an unknown RF input to the load during application of the known low-frequency input; measuring a second output temperature of the thermal medium during application of the known low-frequency input and the unknown RF input; reducing the known low-frequency input while measuring the output temperature of the thermal medium until the output temperature is substantially equal to the first output temperature; determining a value of the known low-frequency input when the output temperature is substantially equal to the first output temperature; and calculating power of the RF input based on the difference between the predetermined value of the known low-frequency input and the value of the known low-frequency input when the output temperature is substantially equal to the first output temperature; wherein a single fluid loop comprising a fluid channel path array is configured to vary a flowrate of said thermal medium through said single fluid loop. 10. The method of claim 9 , wherein said method is carried out using a microfabricated RF power calorimeter and said known low-frequency input is an alternating current voltage source or a direct current voltage source. 11. The RF power calorimeter of claim 9 , wherein said fluid channel path array is comprised of a fluid switch in fluid communication with multiple fluid channels, each fluid channel of said fluid channel path array having a different length and/or hydraulic diameter, and each fluid channel of said fluid channel path array has a thermal medium pump. 12. The method as set forth in claim 10 , wherein said thermal medium is a substrate thermally coupled to a heat exchanger, said output temperature is obtained with a Wheatstone bridge temperature sensor, said power calorimeter is configured to measure power between about 100 .mu.W and 100 mW, and said power calorimeter is configured to measure power at frequencies down to 0 Hz and well above 12 GHz. 13. The method as set forth in claim 10 , wherein said RF power calorimeter is further comprised of a non-conductive substrate; wherein said load and output sensor are microfabricated on said non-conductive substrate.