Solid state microwave generator

What is claimed is: 1. An apparatus comprising: a spin torque oscillator configured to receive a current and to generate a microwave output signal; a sensor configured to detect the microwave output signal and to detect changes to frequency of the detected microwave output signal responsive to changes an external magnetic field, wherein the sensor comprises: an antiferromagnetic layer receiving a current associated with the microwave output signal that is detected by the sensor, wherein the current associated with the microwave output signal is received through a lead; a magnetic pinned layer disposed over the antiferromagnetic layer, wherein exchange coupling between the magnetic pinned layer and the antiferromagnetic layer exchange creates a magnetization in a first direction within the magnetic pinned layer, wherein the magnetic pinned layer receives the current associated with the microwave output signal from the antiferromagnetic layer; a reference layer disposed over the magnetic pinned layer, wherein antiparallel coupling between the reference layer and the magnetic pinned layer creates another magnetization in a second direction within the reference layer, wherein the reference layer polarizes spin of electrons of the current associated with the microwave output signal received from the magnetic pinned layer; and a free magnetization layer disposed over the reference layer, wherein the polarized electrons apply a torque to the free magnetization layer; and a processing unit configured to receive a sensed signal from the sensor, wherein the processing unit is further configured to process the sensed signal and the changes to the frequency to determine magnitude and direction associated with the external magnetic field. 2. The apparatus of claim 1 , wherein the spin torque oscillator comprises: a spin reference layer having a first magnetization direction, wherein the spin reference layer is configured to receive the current and to generate a spin-polarized current; and a spin oscillation layer having a second magnetization direction, wherein the second magnetization direction is different than the first magnetization direction, wherein the spin oscillation layer is configured to receive the spin-polarized current from the spin reference layer, wherein the spin-polarized current generates a spin torque based on the second magnetization direction of the spin oscillation layer, and wherein the spin torque generates the microwave output signal. 3. The apparatus of claim 2 further comprising: an exchange breaking layer configured to magnetically decouple the spin reference layer from the spin oscillation layer. 4. The apparatus of claim 2 , wherein the external magnetic field partially overlaps the spin oscillation layer, and wherein the second magnetization direction is aligned in a same magnetization direction as the external magnetic field. 5. The apparatus of claim 2 , wherein a frequency associated with the microwave output signal is adjustable by varying a density associated with the current. 6. The apparatus of claim 2 , wherein the spin reference layer generates a spin-polarized current by filtering electrons having a first spin direction substantially similar to the first magnetization direction and scattering electrons having a second spin direction substantially opposite to the first magnetization direction. 7. The apparatus of claim 2 , wherein the spin reference layer is selected from the group consisting of a copper-platinum alloy, and an iron-platinum alloy, and wherein the spin oscillation layer is selected from the group consisting of a nickel-alloy, an iron-alloy, and a cobalt-alloy. 8. The apparatus of claim 1 , wherein the sensor detects a change in orientation of a rotational axis oscillation frequency of a magnetization of a magnetic layer in response to changes in orientation of the external magnetic field. 9. The apparatus of claim 1 , wherein the processing unit is configured to measure resistance across an antiferromagnetic layer, a magnetic pinned layer, a reference layer, and a free magnetization layer, and wherein the resistance changes responsive to changes in orientation and magnitude of the external magnetic field. 10. The apparatus of claim 9 , wherein the resistance changes responsive to changes in orientation and magnitude of magnetization of the free magnetization layer. 11. The apparatus of claim 9 , wherein the changes to the frequency is measured by measuring the changes to the resistance. 12. The apparatus of claim 1 further comprising a transmitter coupled to spin torque oscillator to transmit the microwave output signal. 13. A system comprising: a first spin torque oscillation generator configured to generate a first microwave output signal; a second spin torque oscillation generator configured to generate a second microwave output signal, wherein the first microwave output signal is combined with the second microwave output signal to form a resultant microwave output signal; a transmitter coupled to the first spin torque oscillation generator and the second spin torque oscillation generator, wherein the transmitter is configured to output the resultant microwave output signal; a sensor configured to detect the resultant microwave output signal and to detect changes to frequency of the detected resultant microwave output signal responsive to changes in an external magnetic field, wherein the sensor comprises: an antiferromagnetic layer receiving a current associated with the microwave output signal that is detected by the sensor, wherein the current associated with the microwave output signal is received through a lead; a magnetic pinned layer disposed over the antiferromagnetic layer, wherein exchange coupling between the magnetic pinned layer and the antiferromagnetic layer exchange creates a magnetization in a first direction within the magnetic pinned layer, wherein the magnetic pinned layer receives the current associated with the microwave output signal from the antiferromagnetic layer; a reference layer disposed over the magnetic pinned layer, wherein antiparallel coupling between the reference layer and the magnetic pinned layer creates another magnetization in a second direction within the reference layer, wherein the reference layer polarizes spin of electrons of the current associated with the microwave output signal received from the magnetic pinned layer; and a free magnetization layer disposed over the reference layer, wherein the polarized electrons apply a torque to the free magnetization layer; and a processing unit configured to receive a sensed signal from the sensor, wherein the processing unit is further configured to process the sensed signal and the changes to the frequency to determine magnitude and direction associated with the external magnetic field. 14. The system of claim 13 , wherein the first spin torque oscillation generator and the second spin torque oscillation generator each comprise: a spin reference layer having a first magnetization direction, the spin reference layer configured to receive a current and generate a spin-polarized current; and a spin oscillation layer having a second magnetization direction, wherein the second magnetization direction is different than the first magnetization direction, wherein the spin oscillation layer is configured to receive the spin-polarized current from the spin reference layer, wherein the spin-polarized current generates a spin torque based on the second magnetization direction of the spin oscillation layer, and wherein the spin torque generates a microwave output signal, wherein a first magnetizatio