Dual band WLAN coupled radiator antenna

We claim: 1. A dual band antenna, comprising: a planar dielectric substrate having a first surface and a second surface opposite the first surface; a conductive layer situated on the second surface of the planar dielectric substrate, the conductive layer defining a conductive ground plane and a nonconductive keepout area; first, second, and third radiating conductors defined on a first surface of the planar dielectric substrate in an antenna area that is opposite the nonconductive keepout area, the first, second, and third radiating conductors without direct electrical connection to the conductive ground plane, wherein the second and the third radiating conductors are spaced apart from the first radiating conductor and are capacitively coupled to the first radiating conductor without conductive coupling, wherein the first radiating conductor is a conductive rectangle; and a transmitter feed line in electrical contact with the first radiating conductor and configured to communicate a radio frequency electrical signal, wherein the first radiating conductor is selected based on a quarter wavelength at a first frequency in a first frequency band, the second radiating conductor is selected based on a half wavelength at a frequency in a second frequency band different from the first frequency band, the third radiating conductor is selected based on a half wavelength at a second frequency in the first frequency band, and an effective length of the first radiating conductor corresponds to the quarter wavelength at the first frequency. 2. The dual band antenna of claim 1 , wherein the second radiating conductor consists of a conductive area that is a rectangle or is defined by two connected rectangles that form an L-shape and an effective length of the second radiating conductor corresponds to the half wavelength at the frequency in the second frequency band. 3. The dual band antenna of claim 1 , wherein the third radiating conductor consists of a conductive area that is a rectangle or is defined by two connected rectangles that form an L-shape and an effective length of the third radiating conductor corresponds to the half wavelength at the second frequency in the first frequency band. 4. The dual band antenna of claim 1 , wherein the first frequency and the second frequency in the first frequency band are different frequencies. 5. The dual band antenna of claim 1 , wherein the second radiating conductor is defined by two connected rectangles that form an L-shape and has an effective length that corresponds to the half wavelength at the frequency in the second frequency band. 6. The dual band antenna of claim 1 , wherein the first, second and third radiating conductors are configured to preferentially radiate RF power away from the second surface of the substrate in response to an applied RF signal. 7. The dual band antenna of claim 1 , wherein the second radiating conductor is defined by two connected rectangles that form an L-shape and has an effective length that corresponds to the half wavelength at the frequency in the second frequency band and extends across a central lengthwise axis of the first radiating conductor, and wherein the first frequency band is at about 5-6 GHz and the second frequency band is at about 2-3 GHz. 8. A method, comprising: receiving RF power in first and second frequency bands at a first planar antenna section lacking a conductive path to a ground plane and configured to radiate RF power in the first frequency band, wherein the first planar antenna section has an effective length corresponding to a quarter wavelength at a first frequency in the first frequency band, wherein the first planar antenna section is a conductive rectangle; capacitively coupling the RF power in at least the first frequency band from the first planar antenna section to a second planar antenna section lacking a conductive path to a ground plane and configured to radiate RF power in the first frequency band, wherein the second planar antenna section has an effective length corresponding to a half wavelength at a second frequency in the first frequency band, wherein the second planar antenna section is defined as a conductive rectangle or by two connected conductive rectangles that form an L-shape, and capacitively coupling the RF power in at least the second frequency band from the first planar antenna section to a third planar antenna section lacking a conductive path to a ground plane and configured to radiate RF power in the second frequency band, wherein the third planar antenna section has an effective length corresponding to a half wavelength in the second frequency band, wherein the third planar antenna section is defined as a conductive rectangle or by two connected conductive rectangles that form an L-shape, wherein the first, second, and third planar antenna sections are situated on a first surface of a substrate opposite a keepout area defined in a conductive layer on a second surface of the substrate. 9. The method of claim 8 , wherein the first and second planar antenna sections have different peak radiation frequencies in the first frequency band. 10. The method of claim 9 , wherein the first frequency band is at about 5-6 GHz and the second frequency band is at about 2-3 GHz. 11. The method of claim 8 , wherein the second and third planar antenna sections have effective lengths corresponding to integer multiples of ½ wavelength in the associated frequency bands. 12. A wireless networking apparatus, comprising: a dual band antenna; a transceiver configured to receive RF signals from the antenna and couple RF signals to the antenna, wherein the antenna comprises first, second, and third patch antenna sections defined by respective planar conductive patches situated on a first surface of a planar substrate opposite a nonconductive keepout area defined in a ground conductive layer on a second surface of the planar substrate, wherein the second and third patch antenna sections are capacitively coupled to the first patch antenna section without conductive electrical connection to the first patch antenna section and to ground, and the first patch antenna section is conductively coupled to the transceiver, wherein the first and second patch antenna sections are configured for wireless communication in a first frequency band, wherein one of the first and second patch antenna sections has a length associated with a quarter wavelength at a frequency in the first frequency band, and the third patch antenna section is an L-shaped conductive patch having an effective length associated with a second frequency band, wherein the first frequency band is at about 5-6 GHz and the second frequency band is at about 2-3 GHz, and further wherein the first patch antenna section is a conductive rectangle, the second patch antenna section is defined as a conductive rectangle or as first and second conductive rectangles that form an L-shape, and the third patch antenna section is defined by first and second conductive rectangles that form the L-shape. 13. The apparatus of claim 12 wherein the conductive patches of the first, second, and third patch antenna sections are configured to transmit and receive radiation preferentially from a selected side of the substrate. 14. The apparatus of claim 13 , wherein the conductive patches of the first and second patch antenna sections have effective lengths corresponding to ¼ wavelength for RF signals in the first frequency band, and the effective length of the third antenna patch section corresponds to ½ wavelength for RF signals in the second frequency band.