Overview This process occurs in a
resonant transformer, an electrical component which transformer consists of high
Q coil wound on the same core with a
capacitor connected across a coil to make a coupled
LC circuit. The most basic resonant inductive coupling consists of one drive coil on the primary side and one resonance circuit on the secondary side. When the system is not in the resonance state, this leads to the open-circuit voltage appearing at the secondary being less than predicted by the turns ratio of the coils. The degree of coupling is captured by a parameter called
coupling coefficient. The coupling coefficient, , is defined as the ratio of transformer open-circuit voltage ratio to the ratio that would be obtained if all the flux coupled from one coil to the other. However, if it is not open circuit, the flux ratio will change. The value of lies between 0 and ±1. Each coil inductance can be notionally divided into two parts in the proportions . These are respectively an inductance producing the mutual flux and an inductance producing the leakage flux. Coupling coefficient is a function of the geometry of the system. It is fixed by the positional relationship between the two coils. The coupling coefficient does not change between when the system is in the resonance state and when it is not in the resonance state, or even if the system is in resonance state and a secondary voltage larger than the turns ratio is generated. However, in the resonance case, the flux ratio changes and the mutual flux increases. Resonant systems are said to be tightly coupled, loosely coupled, critically coupled or overcoupled. Tight coupling is when the coupling coefficient is around 1 as with conventional iron-core transformers. Overcoupling is when the secondary coil is so close and the formation of mutual flux is hindered by the effect of antiresonance, and critical coupling is when the transfer in the passband is optimal. Loose coupling is when the coils are distant from each other, so that most of the flux misses the secondary. In Tesla coils around 0.2 is used, and at greater distances, for example for inductive wireless power transmission, it may be lower than 0.01.
Voltage gain (Type P-P) Generally the voltage gain of non resonantly coupled coils is directly proportional to the square root of the ratio of secondary and primary inductances. :A = k \sqrt{\frac{L_2}{L_1}} \, However, if in the state of resonant coupling, higher voltage is generated. The
short-circuit inductance Lsc2 on the secondary side can be obtained by the following formula. :L_{sc2}=(1-k^2)\cdot{L_2} The short-circuit inductance Lsc2 and the resonance capacitor Cr on the secondary side resonate. The resonance frequency ω2 is as follows. :\omega_2 = {1 \over \sqrt{L_{sc2} C_r}} = {1 \over \sqrt{(1-k^2)\cdot{L_2} C_r}} Assuming that the load resistance is Rl, the Q value of the secondary resonance circuit is as follows. :Q_2 = R_l \sqrt{\frac{C_r}{L_{sc2}}} \, The voltage generated in the resonance capacitor Cr at the peak of the resonance frequency is proportional to the Q value. Therefore, the voltage gain Ar of the secondary coil with respect to the primary coil when the system is resonating, :A_r = kQ_2 \sqrt{\frac{L_2}{L_1}} \, In the case of the Type P-P, Q1 does not contribute to the voltage gain.
WiTricity type resonant inductive coupling system The
WiTricity type magnetic resonance is characterized in that the resonant coils on the primary side and the resonant coils on the secondary side are paired. The primary resonant coil increases the primary driving coil current and increases the generated magnetic flux around the primary resonator. This is equivalent to driving the primary coil at high voltage. In the case of the type on the left figure, the general principle is that if a given oscillating amount of energy (for example a pulse or a series of pulses) is placed into a primary coil which is capacitively loaded, the coil will 'ring', and form an oscillating magnetic field. Resonant transfer works by making a coil
ring with an oscillating current. This generates an oscillating
magnetic field. Because the coil is highly resonant, any energy placed in the coil dies away relatively slowly over very many cycles; but if a second coil is brought near it, the coil can pick up most of the energy before it is lost, even if it is some distance away. The fields used are predominantly non-radiative,
near fields (sometimes called
evanescent waves), as all hardware is kept well within the 1/4 wavelength distance they radiate little energy from the transmitter to infinity. The energy will transfer back and forth between the magnetic field in the inductor and the electric field across the capacitor at the resonant frequency. This oscillation will die away at a rate determined by the gain-bandwidth (
Q factor), mainly due to resistive and radiative losses. However, provided the secondary coil cuts enough of the field that it absorbs more energy than is lost in each cycle of the primary, then most of the energy can still be transferred. Because the
Q factor can be very high, (experimentally around a thousand has been demonstrated with air
cored coils) only a small percentage of the field has to be coupled from one coil to the other to achieve high efficiency, even though the field dies quickly with distance from a coil, the primary and secondary can be several diameters apart. It can be shown that a figure of merit for the efficiency is: :U = k \sqrt{Q_1 Q_2} Where
Q1 and
Q2 are the Q factors of the source and receiver coils respectively, and
k is the coupling coefficient described above. And the maximum achievable efficiency is: To progressively feed energy into the primary coil with each cycle, different circuits can be used. One circuit employs a
Colpitts oscillator. In Tesla coils an intermittent switching system, a "circuit controller" or "break," is used to inject an impulsive signal into the primary coil; the secondary coil then rings and decays.
Receiver coils and circuitry The secondary receiver coils are similar designs to the primary sending coils. Running the secondary at the same resonant frequency as the primary ensures that the secondary has a low
impedance at the transmitter's frequency and that the energy is optimally absorbed. To remove energy from the secondary coil, different methods can be used, the AC can be used directly or
rectified and a regulator circuit can be used to generate DC voltage. ==See also==