Seat assembly having an adjustable head restraint

What is claimed is: 1. A seat assembly, comprising: a seat back; an adjustable head restraint assembly connected to the seat back; and a sensor located in the seat assembly, adapted to detect when an occupant is present in the seat assembly, and adjust the head restraint assembly based on a determined size and spatial location of the occupant, wherein the spatial location of the occupant is determined based on computing triangulated locations of at least two body organs of the occupant. 2. The seat assembly of claim 1 , wherein the sensor is adapted to identify and measure a biometric signal. 3. The seat assembly of claim 2 , wherein the biometric signal is at least one of a heart beat, a respiratory signal, and a neurological signal. 4. The seat assembly of claim 2 , wherein the sensor is a radar sensor. 5. The seat assembly of claim 1 , wherein the sensor is located in or on the head restraint assembly. 6. The seat assembly of claim 5 , wherein the sensor is a non-contact neuro-monitoring sensor capable of detecting and measuring neuroelectric activity. 7. The seat assembly of claim 1 , wherein the head restraint assembly is capable of moving towards a non-use position when no occupant is detected, and the head restraint assembly is capable of moving towards an in-use position when an occupant is detected. 8. The seat assembly of claim 1 , wherein the body organs include brain of the occupant, heart of the occupant, and lungs of the occupant. 9. The seat assembly of claim 1 , wherein signals from the sensor are filtered to compute triangulated location of at least two body organs of the occupant. 10. The seat assembly of claim 1 , wherein the sensor comprises at least one transmitter and at least one receiver. 11. The seat assembly of claim 10 , wherein the at least one transmitter transmits a wave of energy and the at least one receiver receives a reflected energy wave. 12. The seat assembly of claim 11 , wherein the at least one receiver sends a reflected energy wave signal to a controller. 13. The seat assembly of claim 12 , wherein the reflected energy wave signal comprises time and angle of arrival information. 14. A seat assembly, comprising: a seat back; a head restraint assembly, disposed on the seat back; a head restraint adjustment assembly, connected to the head restraint assembly and configured to adjust the head restraint assembly; a sensor attached to the seat assembly, configured to detect an occupant when present; and a controller in communication with the sensor, configured to: determine a size and a spatial location of the occupant when present, wherein the spatial location of the occupant is determined based on computing triangulated locations of at least two body organs of the occupant, and send an adjustment signal to the head restraint adjustment assembly to move the head restraint assembly towards an in-use position when the occupant is present, and move the head restraint assembly towards a non-use position when the occupant is absent. 15. The seat assembly of 14 , wherein the sensor is a radar sensor. 16. The seat assembly of claim 14 , wherein the sensor is a non-contact neuro-monitoring sensor capable of detecting and measuring neuroelectric activity. 17. The seat assembly of claim 16 , wherein the neuro-monitoring sensor is disposed on the head restraint assembly. 18. A method comprising: detecting an occupant when present in the seat using a sensor; determining a size and a spatial location of the occupant using the sensor, wherein the spatial location of the occupant is determined based on computing triangulated locations of at least two body organs of the occupant; and adjusting a head restraint that is adjustably coupled to a seat back of a seat in response to the determined size and the determined spatial location. 19. The method of claim 18 , wherein the sensor is one of a bladder system capable of measuring a pressure, a radar sensor, and a non-contact neuro-monitoring sensor capable of detecting and measuring neuroelectric activity. 20. The method of claim 19 , wherein the non-contact neuro-monitoring sensor is disposed on the head restraint.