Surgical alignment by magnetic field gradient localization

What is claimed is: 1. A system comprising: a first sensor configured to be inserted in a patient during a surgical procedure, the first sensor comprising: a first magnetic sensor configured to detect a first magnetic field value, a first integrated circuit chip configured to process data from the first magnetic sensor, and a first radiofrequency coil configured to transmit data processed by the first integrated circuit chip based on the first magnetic field; a second sensor attached to a surgical instrument, the second sensor comprising: a second magnetic sensor configured to detect a second magnetic field value, and a second integrated circuit chip configured to process data from the second magnetic sensor; and a plurality of coils configured to generate a magnetic field gradient within a volume in which the surgical procedure takes place, wherein the magnetic field gradient has a unique field value at each spatial location; wherein the plurality of coils comprises at least: a first elliptical x coil and a second elliptical x coil configured to accept currents flowing in opposite directions to each other; a first elliptical y coil and a second elliptical y coil configured to accept currents flowing in opposite directions to each other, the first and second elliptical y coils laying in a plane parallel to the first and second elliptical x coils, and rotated 90° relative to the first and second elliptical x coils; and a z coil. 2. The system of claim 1 , wherein the first sensor further comprises a battery. 3. The system of claim 1 , wherein the first radiofrequency coil of the first sensor is further configured to wirelessly receive power. 4. The system of claim 1 , wherein the first magnetic sensor and the second magnetic sensor are Hall sensors configured to sense three field components in three orthogonal axis, and the magnetic field gradient is monotonic. 5. The system of claim 1 , wherein the first sensor is configured to be attached in a surgical nail to be inserted in a human bone, the second sensor is configured to be attached to a surgical drill, and the surgical procedure comprises alignment of the surgical drill and of the surgical nail. 6. The system of claim 1 , wherein the first and second magnetic sensors have a magnetic field resolution of at least 3.1 μT, an average power consumption of less than 10 μW, and a field measurement dynamic range of ±35 mT for each magnetic field axis component. 7. The system of claim 1 , wherein the magnetic field gradient is 30 mT/m. 8. The system of claim 1 , wherein the first integrated circuit chip is further configured to time multiplex power allocated to the first magnetic sensor and to the first radiofrequency coil. 9. The system of claim 8 , wherein multiplexing of the first integrated circuit chip comprises: a wake up signal to the first magnetic sensor, received by the first radiofrequency coil; a first time allocation to detect an x component of the magnetic field gradient; a second time allocation to detect a y component of the magnetic field gradient; a third time allocation to detect a z component of the magnetic field gradient; a data transmission through the first radiofrequency coil; and a sleep signal to the first magnetic sensor. 10. The system of claim 1 , further comprising a second radiofrequency coil configured to transmit data processed by the second integrated circuit chip based on the second magnetic field. 11. A system comprising: a first sensor configured to be inserted in a patient during a surgical procedure, the first sensor comprising: a magnetic sensor configured to detect a first magnetic field value, an integrated circuit chip configured to process data from the magnetic sensor, and a radiofrequency coil configured to transmit data processed by the integrated circuit chip based on the first magnetic field; a surgical instrument; a second sensor configured to sense a location of the surgical instrument relative to the first sensor; and a plurality of coils configured to generate a magnetic field gradient within a volume in which the surgical procedure takes place, wherein the magnetic field gradient has a unique field value at each spatial location; wherein the plurality of coils comprises at least: a first elliptical x coil and a second elliptical x coil configured to accept currents flowing in opposite directions to each other; a first elliptical y coil and a second elliptical y coil configured to accept currents flowing in opposite directions to each other, the first and second elliptical y coils laying in a plane parallel to the first and second elliptical x coils, and rotated 90° relative to the first and second elliptical x coils; and a z coil. 12. The system of claim 11 , wherein the second sensor comprises a gyroscope attached to the surgical instrument, or an optical positioning device. 13. A system comprising: a first sensor configured to be inserted in a patient during a surgical procedure, the first sensor comprising: a first magnetic sensor configured to detect a first magnetic field value, a first integrated circuit chip configured to process data from the first magnetic sensor, and a first radiofrequency coil configured to transmit data processed by the first integrated circuit chip based on the first magnetic field; a second sensor attached to a surgical instrument, the second sensor comprising: a second magnetic sensor configured to detect a second magnetic field value, and a second integrated circuit chip configured to process data from the second magnetic sensor; and a plurality of coils configured to generate a magnetic field gradient within a volume in which the surgical procedure takes place, wherein the magnetic field gradient has a unique field value at each spatial location; wherein the first integrated circuit chip is further configured to time multiplex power allocated to the first magnetic sensor and to the first radiofrequency coil; and wherein multiplexing of the first integrated circuit chip comprises: a wake up signal to the first magnetic sensor, received by the first radiofrequency coil; a first time allocation to detect an x component of the magnetic field gradient; a second time allocation to detect a y component of the magnetic field gradient; a third time allocation to detect a z component of the magnetic field gradient; a data transmission through the first radiofrequency coil; and a sleep signal to the first magnetic sensor.