Simultaneous launching of multiple signal channels in a dielectric waveguide using different electromagnetic modes

What is claimed is: 1. A signal transmitting device comprising: a multilayer substrate having a first surface and an opposite second surface, with an edge surface arranged between the first surface and the second surface; a first transmitter circuit having a radio frequency (RF) output port; a vertical antenna formed within the substrate between the first surface and the second surface and adjacent to the edge surface, in which the vertical antenna is a dipole antenna oriented perpendicular to the first surface; in which a first arm extends toward the first surface from a first middle conductive layer of the multilayer substrate and in which a second arm extends toward the second surface from a second middle conductive layer of the multilayer substrate; and in which the first arm and the second arm are coupled to the output port of the first transmitter. 2. The device of claim 1 , in which the first arm and the second arm each extend through a plurality of conductive layers of the multilayer substrate and in which a conductive fishbone rib structure is formed in each of the plurality of conductive layers and coupled to the respective first arm and second arm. 3. The device of claim 1 , further including: a second transmitter circuit having a radio frequency (RF) output port; a horizontal antenna formed on a third middle conductive layer within the substrate between the first surface and the second surface and adjacent to the edge surface, in which the horizontal antenna is a dipole antenna with a first arm and a second arm oriented parallel to the first surface; and in which the first arm and the second arm of the horizontal antenna are coupled to the output port of the second transmitter. 4. The device of claim 3 , in which the first transmitter circuit and the second transmitter circuit are included within a single transmitter having multiple outputs. 5. The device of claim 3 , in which the first transmitter is configured to form an in-phase modulated signal and the second transmitter is configured to form a quadrature phase modulated signal. 6. A signal transmitting device comprising: a multilayer substrate having a first dielectric surface and an opposite second surface, with an edge surface arranged between the first dielectric surface and the second surface; a first transmitter circuit having a radio frequency (RF) output port; a second transmitter having a radio frequency (RF) output port; a first antenna having arms parallel to the first dielectric surface and coupled to the output port of the first transmitter circuit configured to launch an electromagnetic wave into a dielectric waveguide (DWG) using a first transmission mode; and a second antenna having arms perpendicular to the first dielectric surface and coupled to the output port of the second transmitter circuit configured to launch an electromagnetic wave into the DWG using a second transmission mode, in which the second transmission mode is orthogonal to the first transmission mode. 7. The device of claim 6 , in which the first transmitter circuit and the second transmitter circuit are included within a single transmitter. 8. The device of claim 6 , in which the first transmitter circuit is configured to form an in-phase modulated signal and the second transmitter circuit is configured to form a quadrature phase modulated signal. 9. The device of claim 6 , further comprising: a first filter circuit coupled to the first transmitter circuit with an output coupled to the first antenna; and a second filter circuit coupled to the second transmitter circuit with an output coupled to the second antenna. 10. The device of claim 6 , in which the first antenna is a dipole antenna formed from a conductive layer of the multilayer substrate; and in which the second antenna is a vertical dipole antenna oriented perpendicular to the first dielectric surface; in which a first arm extends toward the first dielectric surface from a first middle conductive layer of the multilayer substrate and in which a second arm extends toward the second surface from a second middle conductive layer of the multilayer substrate. 11. The device of claim 10 , in which the first arm and the second arm each extend through a plurality of conductive layers of the multilayer substrate and in which a conductive fishbone rib structure is formed in each of the plurality of conductive layers and coupled to the respective first arm and second arm. 12. The device of claim 6 , in which the first antenna and the second antenna form a combined patch antenna having a grid of conductive rows and columns. 13. The device of claim 12 , in which the patch antenna is oriented perpendicular to the first dielectric surface and parallel to the edge surface. 14. The device of claim 6 , in which the first antenna is a log periodic antenna formed on one or more conductive layers of the multilayer substrate and oriented parallel to the first dielectric surface. 15. The device of claim 6 , in which the second antenna includes a plurality of vertical dipoles to form a log periodic antenna oriented perpendicular to the first dielectric surface. 16. The device of claim 15 , in which each of the vertical dipoles extends through a plurality of conductive layers of the multilayer substrate and in which a plurality of conductive fishbone rib structures is formed in each of the plurality of conductive layers and coupled to respective ones of the plurality of vertical dipoles. 17. The device of claim 6 , further including a dielectric waveguide coupled to simultaneously receive a signal launched by the first antenna and by the second antenna. 18. A method for transmitting multiple channels of information through a dielectric waveguide, the method comprising: generating a first radio frequency signal (RF) and a second RF signal; launching the first RF signal into a dielectric waveguide (DWG) using a first antenna having arms formed parallel to a dielectric layer of a multilayer substrate to excite a first transmission mode of the DWG; and launching the second RF signal into the DWG using a second antenna having arms formed perpendicular to the dielectric layer of the multilayer substrate to excite a second transmission mode of the DWG, in which the second transmission mode is orthogonal to the first transmission mode. 19. The method of claim 18 , in which the first antenna is a dipole antenna formed from a conductive layer of the multilayer substrate; and in which the second antenna is a vertical dipole antenna in which a first arm extends above the dielectric layer of the multilayer substrate and in which a second arm extends below the dielectric layer of the multilayer substrate. 20. The method of claim 18 , in which the first antenna and the second antenna form a combined patch antenna having a grid of conductive rows and columns formed within the multilayer substrate.