Battery antenna having a secondary radiator

What is claimed is: 1. A combination battery and antenna, comprising: a battery having a positive contact and a negative contact, wherein only one of the positive contact and the negative contact comprises an antenna coupled to a matching circuit and to a battery circuit assembly comprising a radio frequency choke, and wherein the other one of the positive contact and the negative contact is electrically coupled to a ground plane, wherein the ground plane comprises a direct current (DC) ground and a radio frequency (RF) ground, whereby DC is supplied to the battery circuit assembly and an RF signal is supplied to an RF circuit; and at least one secondary radiator parasitically coupled to the at least one of the positive contact and the negative contact of the battery, and further electrically coupled to the ground plane, wherein the at least one secondary radiator is a metallic structure formed from a metallic material that is also used to form the ground plane, the secondary radiator being connected to the negative contact of the battery. 2. The combination battery and antenna of claim 1 , wherein the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator operate as an antenna at a plurality of radio frequency bands. 3. The combination battery and antenna of claim 1 , wherein the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator operate as an antenna within a radio frequency band, the at least one of the positive contact and the negative contact of the battery provides a first radio frequency band, and the at least one secondary radiator widens the first radio frequency band to a second radio frequency band. 4. The combination battery and antenna of claim 1 , further comprising an antenna matching circuit connected to the at least one of the positive contact and the negative contact of the battery, the antenna matching circuit comprising any of a capacitive (C) and an inductive (L) structure configured to allow the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator to function as an antenna in a predetermined frequency range. 5. The combination battery and antenna of claim 4 , wherein the predetermined frequency range is approximately 2.4 GHz to approximately 2.5 GHz. 6. A method of using a battery as an antenna, the method comprising: providing a battery having a positive contact and a negative contact, wherein only one of the positive contact and the negative contact comprises an antenna coupled to a matching circuit and to a battery circuit assembly comprising a radio frequency choke, and wherein the other one of the positive contact and the negative contact is electrically coupled to a ground plane, wherein the ground plane comprises a direct current (DC) ground and a radio frequency (RF) ground; supplying DC to the battery circuit assembly and an RF signal to an RF circuit; parasitically coupling at least one secondary radiator to the at least one of the positive contact and the negative contact of the battery, wherein the at least one secondary radiator is a metallic structure formed from a metallic material that is also used to form the ground plane, the secondary radiator being connected to the negative contact of the battery; and electrically coupling the at least one secondary radiator to the ground plane. 7. The method of claim 6 , further comprising operating the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator as an antenna at a plurality of radio frequency bands. 8. The method of claim 6 , further comprising operating the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator as an antenna within a radio frequency band, the at least one of the positive contact and the negative contact of the battery providing a first radio frequency band, and the at least one secondary radiator widening the first radio frequency band to a second radio frequency band. 9. The method of claim 6 , further comprising connecting an antenna matching circuit to the at least one of the positive contact and the negative contact of the battery, the antenna matching circuit comprising any of a capacitive (C) and an inductive (L) structure configured to allow the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator to function as an antenna in a predetermined frequency range. 10. The method of claim 9 , wherein the predetermined frequency range is approximately 2.4 GHz to approximately 2.5 GHz. 11. A radio frequency (RF) communication device, comprising: a baseband subsystem; a transceiver operatively coupled to the baseband subsystem; a battery having a positive contact and a negative contact, wherein only one of the positive contact and the negative contact comprises an antenna coupled to a matching circuit and to a battery circuit assembly comprising an RF choke, and wherein the other one of the positive contact and the negative contact is electrically coupled to a ground plane, wherein the ground plane comprises a direct current (DC) ground and an RF ground, whereby DC is supplied to the battery circuit assembly and an RF signal is supplied to an RF circuit; and at least one secondary radiator parasitically coupled to the at least one of the positive contact and the negative contact of the battery, and further electrically coupled to the ground plane, wherein the at least one secondary radiator is a metallic structure formed from a metallic material that is also used to form the ground plane, the secondary radiator being connected to the negative contact of the battery. 12. The communication device of claim 11 , wherein the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator operate as an antenna at a plurality of radio frequency bands. 13. The communication device of claim 11 , wherein the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator operate as an antenna within a radio frequency band, the at least one of the positive contact and the negative contact of the battery provides a first radio frequency band, and the at least one secondary radiator widens the first radio frequency band to a second radio frequency band. 14. The communication device of claim 11 , further comprising an antenna matching circuit connected to the at least one of the positive contact and the negative contact of the battery, the antenna matching circuit comprising any of a capacitive (C) and an inductive (L) structure configured to allow the at least one of the positive contact and the negative contact of the battery and the at least one secondary radiator to function as an antenna in a predetermined frequency range. 15. The communication device of claim 14 , wherein the predetermined frequency range is approximately 2.4 GHz to approximately 2.5 GHz. 16. A combination battery and antenna, comprising: a circuit card assembly having a ground plane, wherein the ground plane comprises a direct current (DC) ground and a radio frequency (RF) ground; a battery located over the circuit card assembly, the battery having a positive contact and a negative contact, wherein only one of the positive contact and the negative contact comprises an antenna coupled to a matching circuit and to a battery circuit assembly comprising a radio frequen