Self calibrating micro-fabricated load cells

What is claimed is: 1. A self calibrating load cell, comprising: a resonant double ended tuning fork force sensor; and a phase locked loop circuit for detection of frequency changes upon external load application to the resonant double ended tuning fork force sensor; wherein the resonant double ended tuning fork sensor has a zero-load resonance frequency (ω n,o,op ) and a zero-load scale factor (α o,op ); and wherein, during calibration, a load on the resonant double ended turning fork force sensor is obtained according to a calibration curve equation: F appl =(ω 2n,0p −ω 2 n,o,0p )/(2*α o,op *ω n,o,0p ). 2. The self calibrating load cell of claim 1 , wherein the resonant double ended tuning fork force sensor comprises at least one sense electrode; at least one drive electrode; a resonant tuning fork; a spring supported roller; and a load cell tip for application of the external load. 3. The self calibrating load cell of claim 2 , wherein the spring supported roller is situated between the resonant tuning fork and the load cell tip. 4. The self calibrating load cell of claim 1 , wherein the phase locked loop circuit comprises a pre-amplifier stage; a phase detector; a controller; and a voltage controlled oscillator (VCO). 5. The self calibrating load cell of claim 1 , wherein the resonant double ended tuning fork force sensor and a phase locked loop circuit are assembled on a printed circuit board (PCB). 6. The self calibrating load cell of claim 5 , wherein the PCB dimensions are 65 mm×52 mm. 7. The self calibrating load cell of claim 1 , wherein the resonant double ended tuning fork force sensor is implemented with a silicon-on-insulator (SOI) process with 100 μm silicon structural layer. 8. The self calibrating load cell of claim 7 , wherein the silicon-on-insulator (SOI) process comprises: etching a device layer of a wafer; removing photoresist residues from the wafer; attaching the wafer to a secondary handle wafer and etching the backside of the wafer; removing the secondary handle wafer from the device wafer; cleaning the device wafer; and separating the devices without dicing. 9. The self calibrating load cell of claim 1 , wherein the resonant double ended tuning fork force sensor has a resolution of up to 7 nN and a compressive load range of up to 0.085N, exceeding a dynamic range of 140 dB (100 parts per billion). 10. The self calibrating load cell of claim 1 , wherein the resonant double ended tuning fork force sensor has a scale factor of 216 kHz/N, a Q-factor greater than 60,000 at 3 mTorr ambient pressure and a zero load resonant frequency of up to 47.6 kHz. 11. A method of characterization, comprising: calibrating a resonant double ended tuning fork sensor, wherein the calibrating comprises performing a load test with the resonant double ended tuning fork force sensor prior to its use to obtain a zero-load resonance frequency (ω n,o,op ) and a zero-load scale factor (α o,op ); and during application of external force, obtaining the zero-load resonance frequency (ω n,o,op ) and zero-load scale factor (α o,op ) as a function of detected frequency change; applying external axial force (compressive or tensile) to a resonant double ended tuning fork force sensor, wherein a natural frequency of tines of resonant double ended tuning fork force sensor decreases or increases in response to the applied external axial force; and detecting the decrease or increase in natural frequency by means of a circuitry comprising a phase locked loop circuit; wherein, during calibration, a load on the resonant double ended turning fork force sensor is obtained according to a calibration curve equation: F appl =(ω 2n,0p −ω 2 n,o,0p )/(2*α o,op *ω n,o,0p ). 12. The method of claim 11 , wherein the resonant double ended tuning fork force sensor comprises: at least one sense electrode; at least one drive electrode; a resonant tuning fork; a spring supported roller; and a load cell tip for application of the external load. 13. The method of claim 11 , wherein the phase locked loop circuit comprises: a pre-amplifier stage; a phase detector; a controller; and a voltage controlled oscillator (VCO). 14. The method of claim 11 , wherein the phase locked loop circuit and resonant double ended tuning fork force sensor are assembled on a printed circuit board (PCB). 15. A load cell assembled on a printed circuit board (PCB), comprising: a force sensor; and a circuit for detection of frequency changes upon external load application to the force sensor; wherein the force sensor has a zero-load resonance frequency (ω n,o,op ) and a zero-load scale factor (α o,op ); and wherein, during calibration, a load on the resonant double ended turning fork force sensor is obtained according to a calibration curve equation: F appl =(ω 2n,0p −ω 2 n,o,0p )/(2*α o,op *ω n,o,0p ). 16. The load cell of claim 15 , wherein the force sensor is a resonant double ended tuning fork force sensor. 17. The load cell of claim 15 , wherein the load cell is self calibrating. 18. The load cell of claim 15 , wherein the force sensor is implemented using a silicon-on-insulator process.