Multi-system multi-band antenna assembly with Rotman lens

What is claimed is: 1. An antenna assembly, comprising: a blade antenna for communicating a first signal; a planar antenna array for communicating a second signal, the planar antenna array comprising: an array of antenna elements, the array of antenna elements comprising a plurality antenna elements arranged in rows using the blade antenna as a conductive ground plane; a Rotman lens, formed by using the blade antenna as the conductive ground plane, the Rotman lens having a set of Rotman lens array ports and a set of Rotman lens beam ports, each element of a respective row of the antenna elements communicatively coupled to a respective one port of the set of Rotman lens array ports; a signal processor, having: a set of signal processor first ports, each signal processor first port communicatively coupled to a respective one of the set of Rotman lens beam ports; a second signal processor port, the second signal processor port for communicating the second signal; and wherein the signal processor selectively couples the second signal processor port to one or more of the signal processor first ports. 2. The antenna assembly of claim 1 , wherein: the Rotman lens is disposed on a first side of a substrate; and the blade antenna is formed by the conductive ground plane for the planar antenna array on a second side of the substrate. 3. The antenna assembly of claim 1 , wherein: the antenna assembly comprises a multi-layer substrate comprising a first substrate and a second substrate; the array of antenna elements is disposed on a top side of the first substrate; the blade antenna is formed by a conductive ground plane for the planar antenna array, disposed between the first substrate and the second substrate; the Rotman lens is disposed on a bottom side of the second substrate; and each antenna element of the respective row of the antenna elements is communicatively coupled to the respective ports of the set of Rotman lens array ports via microstrip conductors disposed on the bottom side of the second substrate and slots disposed in the conductive ground plane beneath each antenna element. 4. The antenna assembly of claim 1 , further comprising: an antenna housing having a plurality of sides including a first side and a second side; a further planar antenna array, for communicating the second signal, the further planar antenna array comprising: a further array of antenna elements, the further array of antenna elements comprising a plurality of further antenna elements arranged in further rows; a further Rotman lens having a set of further Rotman lens array ports and a set of further Rotman lens beam ports, each element of a respective further row communicatively coupled to a respective one of further Rotman lens array ports; wherein: the planar antenna array is mounted on the first side of the antenna housing; the further planar antenna array is mounted on the second side of the antenna housing; the signal processor comprises: a set of signal processor further first ports, each signal processor further first port communicatively coupled to a respective one of the set of further Rotman lens beam ports; the signal processor further selectively couples the second signal processor port to one or more of the signal processor further first ports. 5. The antenna assembly of claim 4 , wherein: the antenna housing is mounted to an external surface of a vehicle and wherein the signal processor is disposed within an interior volume of the vehicle. 6. The antenna assembly of claim 4 , wherein: the antenna housing is mounted to an external surface of a vehicle and wherein the signal processor is disposed within the antenna housing. 7. The antenna assembly of claim 6 , wherein: the planar antenna array and the further planar antenna array are directed to collectively provide radiation beams of 360 degrees in azimuth and up to 180 degrees in elevation. 8. The antenna assembly of claim 4 , wherein: the plurality of sides comprises a third side, the antenna housing having a triangular cross section; and the third side comprises a third planar antenna array. 9. The antenna assembly of claim 4 , wherein: the plurality of sides comprises a third side and a fourth side, the antenna housing having a trapezoidal cross section; the third side comprises a third planar antenna array; and the fourth side comprises a fourth planar antenna array. 10. The antenna assembly of claim 1 , wherein a set of Rotman lens ports comprise the set of Rotman lens array ports and the set of Rotman lens beam ports, and wherein the Rotman lens passively transforms the second signal presented at a port of the set of Rotman lens ports from a first phase and first amplitude to one or more signals at one or more other ports of the set of Rotman lens ports having a second phase and second amplitude. 11. The antenna assembly of claim 1 , wherein the first signal is in a first frequency band and the second signal is in a second frequency band higher than the first frequency band. 12. The antenna assembly of claim 11 , wherein: the first frequency band is below 6 GHz; the second frequency band is within 7 to 86 GHz; and the first signal and the second signal are communicated simultaneously. 13. The antenna assembly of claim 1 , wherein the blade antenna is formed by a conductive layer of a substrate. 14. The antenna assembly of claim 13 , wherein each row of the antenna elements is communicatively coupled to a respective one of the set of Rotman lens array ports via a microstrip feed. 15. The antenna assembly of claim 14 , wherein: each signal processor first port is communicatively coupled to a respective one of the set of Rotman lens beam ports by an associated second microstrip conductor. 16. A method of communicating one or more a radio frequency (RF) signals via an antenna assembly, comprising: providing at least one of a first radio frequency (RF) signal and a second RF signal to a planar antenna array of an antenna assembly, the antenna assembly comprising: a blade antenna; the planar antenna array that is configured to utilize the blade antenna as a conductive ground plane, the planar antenna array comprising: an array of antenna elements, the array of antenna elements comprising a plurality antenna elements arranged in rows; and a Rotman lens, using the blade antenna as the conductive ground plane, the Rotman lens having a set of Rotman lens array ports and a set of Rotman lens beam ports, each element of a respective row of the antenna elements communicatively coupled to a respective one port of the set of Rotman lens array ports; and a signal processor, having: a set of signal processor first ports, each signal processor first port communicatively coupled to a respective one of the set of Rotman lens beam ports; a second signal processor port, the second signal processor port for communicating the second RF signal; and wherein the signal processor selectively couples the second signal processor port to one or more of the signal processor first ports; and communicating at least one of the first RF signal via the blade antenna and the second RF signal via the planar antenna array. 17. The method of claim 16 , further comprising: the first RF signal is communicated via the blade antenna and the second RF signal is communicated via the planar antenna array; wherein: the first RF signal is in a first frequency band; the second RF signal is in a second frequency band; the first frequency band is below 6 GHz and the second frequency band is 7 t