Wireless power transmission via inductive coupling using di/dt as the magnetic modulation scheme

What is claimed is: 1. A non-radio frequency carrier based wireless connector set for use in power transmission, comprising: a. a first connector, comprising: i. a first transmission path adapted to be used with a power signal; ii. a first transformer operatively connected to the first transmission path, the first transformer comprising a first inductance; iii. a first alternating voltage source operatively connected to the first transformer, the first alternating voltage source adapted to operate at a first non-radio frequency power transmission frequency; and b. a second connector adapted to be disposed in close proximity to the first connector, comprising: i. a second transmission path adapted to be used with the power signal; and ii. a second transformer operatively connected to the first transmission path, the second transformer adapted to be inductively and cooperatively coupled to the first transformer, the second transformer comprising a second inductance substantially equal to the first inductance. 2. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 1 , wherein the power signal comprises an alternating current power signal. 3. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 1 , wherein the close proximity comprises a distance of no more than around one-half inch. 4. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 1 , wherein the first transformer and the second transformer are further adapted to be located remotely using a coax cable. 5. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 1 , wherein the second inductance comprises a turns ratio of around 1.7 of the first inductance to deliver the desired voltage on the secondary inductance. 6. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 1 , further comprising: a. a first capacitor connected in parallel with the first transformer; and b. a second capacitor connected in parallel with the second transformer. 7. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 6 , wherein the values of the first and second capacitors result in inductor-capacitor (LC) tanks tuned to an operative frequency of the power signal. 8. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 7 , wherein the operative frequency of the power signal comprises a frequency of around 60 Hz. 9. The non-radio frequency carrier based wireless connector set for use in power transmission of claim 6 , wherein the values of the first and second capacitors result in inductor-capacitor (LC) tanks tuned to a harmonic of an operative frequency of the power signal. 10. A system for electrical power transmission, comprising: a. a source of electrical power adapted to transmit power at a first power transmission frequency; b. a first connector operatively in communication with the source of electrical power, the first connector comprising: i. a first low impedance transmission path adapted to be used with an electrical power signal operating at a first frequency; ii. a first housing; iii. a first transformer operatively connected to the first transmission path at the low impedance and disposed at least partially within the housing, the first transformer comprising a first inductance; iv. a first tank circuit operatively connected to the first transformer and disposed at least partially within the first housing, the tank circuit comprising a capacitor connected in parallel with the first transformer; v. a first alternating voltage source operatively connected to the first transformer and disposed at least partially within the first housing; and c. a second connector separate from the first connector, the second connector comprising: i. a second low impedance transmission path adapted to be used with the electrical power signal operating at a frequency substantially the same as the first frequency; ii. a second housing adapted to cooperatively receive the first connector at a first coupled separation distance in close proximity to the first connector in a predetermined environment; iii. a second transformer operatively connected to the first transmission path at a low impedance and disposed at least partially within the second housing, the second transformer adapted to be inductively and cooperatively coupled to the first transformer, the second transformer comprising a second inductance; and iv. a second tank circuit operatively connected to the second transformer and disposed at least partially within the second housing, the tank circuit comprising a capacitor connected in parallel with the second transformer. 11. The system for electrical power transmission of claim 10 , wherein predetermined environment comprises at least one of air, fresh water, seawater, dark water, sand, mud, grit, oil, or vacuum. 12. The system for electrical power transmission of claim 10 , wherein the coupled separation distance is at or less than around one-half inch. 13. An electrical power connector system for use subsea, comprising: a. a selectively retrievable module, comprising: i. a first housing adapted for use subsea; and ii. a first connector disposed at least partially within the first housing, the first connector comprising: 1. a first low impedance transmission path adapted to be used with an electrical power signal operating at a first frequency; 2. a first housing; 3. a first transformer operatively connected to the first transmission path at the low impedance and disposed at least partially within the housing, the first transformer comprising a first inductance; 4. a first tank circuit operatively connected to the first transformer and disposed at least partially within the first housing, the tank circuit comprising a first capacitor connected in parallel with the first transformer; 5. a first alternating voltage source operatively connected to the first transformer and disposed at least partially within the first housing; and b. a module receiver adapted for use subsea, comprising: i. a second housing adapted for use subsea and dimensioned to cooperatively receive the first housing; and ii. a second connector adapted to be in close proximity to the first connector when the first housing is received into the second housing, the second connector comprising: 1. a second low impedance transmission path adapted to be used with the electrical power signal operating at a frequency substantially equal to the first frequency; 2. a second housing adapted to cooperatively receive the first connector at a first coupled separation distance in close proximity to the first connector in a predetermined environment; 3. a second transformer operatively connected to the first transmission path at a low impedance and disposed at least partially within the second housing, the second transformer adapted to be inductively and cooperatively coupled to the first transformer, the second transformer comprising a second inductance; and 4. a second tank circuit operatively connected to the second transformer and disposed at least partially within the second housing, the tank circuit comprising a second capacitor connected in parallel with the second transformer. 14. A method of electrical power transmission, comprising: a. operatively connecting a first connector to a source of electrical power, the first connector comprising: i. a first low impedance transmission