Vehicle cabin mobile device detection system

What is claimed is: 1. A vehicle, comprising: a controller coupled to in-cabin sensor groups each for a different seating location and including antennas each tuned to a different radio access technology (RAT) frequency of a mobile device, the controller configured to detect first and second RAT frequencies from a mobile device using one of the sensor groups, generate mobile device and vehicle commands based on the detected RAT frequencies and the seating location for the one sensor group, and identify, in the seating location for each sensor group, whether a Bluetooth protocol, a WiFi protocol, and a cellular protocol is being used by a mobile device in the seating location using the sensor group for the seating location. 2. The vehicle according to claim 1 , wherein the sensor groups are integrated into a headliner of the cabin, each sensor group is positioned to correspond to the seating location for the sensor group and has an effective range substantially limited to the seating location for the sensor group, and the controller is configured to: determine a seating location of the mobile device based on the seating location for the one sensor group that detects the first and second RAT frequencies from the mobile device; determine a connection status of first and second RATs of the mobile device based on the detected first and second RAT frequencies; and generate the mobile device and vehicle commands based on the determined seating location of the mobile device and the connection status of the first and second RATs of the mobile device. 3. The vehicle according to claim 1 , wherein each sensor group comprises at least one waveguide configured to establish an effective range for the sensor group, the effective range being substantially limited to the seating location for the sensor group. 4. The vehicle according to claim 3 , wherein the at least one waveguide and the antennas of each sensor group are integrated with a seat of the seating location for the sensor group and have a directional orientation configured to project the effective range of the sensor group upwards from the seat of the seating location for the sensor group. 5. The vehicle according to claim 3 , wherein the at least one waveguide and the antennas of each sensor group are integrated into a headliner of the cabin above the seating location for the sensor group, and the at least one waveguide of each sensor group includes a directional orientation configured to project the effective range of the sensor group downward towards the seating location of the sensor group. 6. The vehicle according to claim 1 , wherein the sensor groups each includes a respective signal processor coupled to each of the antennas of the sensor group, and each antenna of each sensor group includes a respective waveguide tuned to the RAT frequency of the antenna. 7. The vehicle according to claim 6 , wherein the antennas and waveguides of each sensor group are integrated into a headliner of the cabin above the seating location for the sensor group, the waveguides of each sensor group are configured to establish an effective range for the sensor group that is substantially limited to the seating location for the sensor group, and the waveguides of each sensor group have a directional orientation configurated to project the effective range of the sensor group downwards towards the seating location of the sensor group. 8. The vehicle according to claim 6 , wherein the antennas and waveguides of each sensor group are integrated with a seat of the seating location for the sensor group, the waveguides of each sensor group are configured to establish an effective range substantially limited to the seating location for the sensor group, and the waveguides of each sensor group have a directional orientation configured to project the effective range of the sensor group upwards from the seat of the seating location for the sensor group. 9. A system comprising: sensor groups each corresponding to a different vehicle seating location and including antennas each tuned to a different mobile device RAT frequency; and a controller coupled to the sensor groups and configured to detect first and second mobile device RAT frequencies using one of the sensor groups, generate a vehicle and/or mobile device command based on the detected RAT frequencies and the seating location for the one sensor group, and identify, in the seating location for each sensor group, whether a Bluetooth protocol, a WiFi protocol, and a cellular protocol is being used by a mobile device in the seating location using the sensor group for the seating location. 10. The system according to claim 9 , wherein each sensor group includes a waveguide for each antenna of the sensor group, the waveguide for each antenna configured to establish an effective range for the antenna that is substantially limited to the seating location for the sensor group. 11. The system according to claim 9 , wherein each antenna of each sensor group is coupled to a different signal processor that is tuned to the RAT frequency of the antenna. 12. The system according to claim 10 , wherein the antennas and waveguides of each sensor group are configured to be integrated into a headliner of a cabin of the vehicle above the seating location for the sensor group and have a directional orientation configured to project the effective range of the sensor group downward towards the seating location of the sensor group. 13. The system according to claim 10 , wherein the antennas and waveguides of each sensor group are configured to be integrated as part of a seat of the seating location for the sensor group and have a directional orientation configured to project the effective range upwards from the seat of the seating location for the sensor group. 14. A method comprising: by a vehicle controller coupled to in-cabin sensor groups each for a different seating location in the cabin and including antennas each tuned to a different RAT frequency of a mobile device detecting first and second RAT frequencies from a mobile device using one of the sensor groups; and generating vehicle and mobile device commands based on the detected RAT frequencies and the seating location for the one sensor group; and identifying, in the seating location for each sensor group, whether a Bluetooth protocol, a WiFi protocol, and a cellular protocol is being used by a mobile device in the seating location using the sensor group for the seating location. 15. The method according to claim 14 , wherein each antenna of each sensor group comprises a waveguide tuned to the RAT frequency of the antenna and configured to establish an effective range substantially limited to the seating location for the sensor group. 16. The method according to claim 14 , wherein each antenna of each sensor group is coupled to a different signal processor tuned to the RAT frequency of the antenna. 17. The method according to claim 15 , wherein the antennas and waveguides of each sensor group are integrated into a headliner of the cabin above a seat of the seating location for the sensor group and have a directional orientation configured to project the effective range of the sensor group downwards towards the seat of the seating location for the sensor group. 18. The method according to claim 15 , wherein the antennas and waveguides of each sensor group are integrated with a seat of the seating location for the sensor group and have a directional orientation configured to project the effective range of the sensor group upwards from the seat of the seating location