Wireless lightning control system for a wind turbine

The invention claimed is: 1. A method for switching on/off a plurality of light sources internal to a wind turbine that includes a tower and a nacelle mounted on and supported by the tower, the method comprising: manipulating one of: a first locally controllable switch located in a bottom portion of the tower and a second locally controllable switch located in the nacelle to switch on a first light source in the wind turbine; at a second light source in the wind turbine, wirelessly receiving a first switch-on signal transmitted from the first light source; and switching on the second light source in response to the wirelessly received first switch-on signal. 2. The method according to claim 1 , wherein the first switch-on signal is received as light from the first light source and a photo-detector at the second light source is used to wirelessly receive the light. 3. The method according to claim 1 , wherein the first switch-on signal is one of a non-visible light signal, a radio frequency signal, and an acoustic signal emitted from a wireless transmitter located at the first light source. 4. The method according to claim 1 , further comprising: at a third light source, wirelessly receiving a second switch-on signal from the second light source; and switching on the third light source in response to the wirelessly received second switch-on signal. 5. The method according to claim 1 , further comprising: switching off the first light source in the wind turbine in response to a second manipulation of the first locally controllable switch; at the second light source, wirelessly receiving a switch-off signal transmitted from the first light source; and switching off the second light source in response to the wirelessly received switch-off signal. 6. The method according to claim 1 , further comprising: switching off the first light source in the wind turbine in response to a second manipulation of the first locally controllable switch; at the second light source, wirelessly sensing that the first light source is switched off using a photo-detector at the second light source; and switching off the second light source in response to sensing that the first light source is switched off. 7. The method of claim 1 , further comprising: switching on a third light source in the wind turbine in response to a manipulation of a second locally controllable switch; at a fourth light source in the wind turbine, wirelessly receiving a switch-on signal transmitted from the third light source; and switching on the fourth light source in response to the switch-on signal wirelessly received from the third light source. 8. A wind turbine comprising: a tower having a first access port for technicians; a nacelle mounted on and supported by the tower and having a second access port for technicians; a plurality of light sources mounted within the tower and the nacelle; and a wireless lighting control system, the wireless lighting control system comprising: a first locally controllable switch for controlling power to the plurality of light sources, the first locally controllable light switch being located proximate to the first access port; a second locally controllable switch for controlling power to the plurality of light sources, the second locally controllable light switch being located proximate to the second access port; and a remotely controllable light switch located at each of one or more of the light sources, the remotely controllable switch being configured to: wirelessly receive a switch-on signal generated in response to manipulation of at least one of the first and second locally controllable switches; and switch on power to the corresponding light source in response to receiving the switch-on signal. 9. The wind turbine according to claim 8 , wherein at least one of the first and second locally controllable switches includes a wireless transmitter configured to generate and transmit the switch-on signal in response to manipulation of the at least one of the first and second locally controllable switches, and wherein the wireless transmitter is one of a visible light source, a non-visible light source, an acoustic transmitter, and a radio frequency transmitter. 10. The wind turbine according to claim 9 , the wireless lighting control system further comprising a wireless transmitter located at each of one or more of the light sources, wherein the switch-on signal is a first switch-on signal, wherein the wireless transmitter is configured to generate a second switch-on signal as at least one of a non-visible light optical signal, a radio frequency signal, and an acoustic signal, and wherein the remotely controllable switch located at each of one or more of the light sources is configured to wirelessly receive the first and/or second switch-on signals and switch on power to the corresponding light source in response to receiving the first and/or second switch-on signals. 11. The wind turbine according to claim 10 , wherein the wireless transmitter of the at least one of the first and second locally controllable switches is further configured to generate and transmit a first switch-off signal, wherein the wireless transmitter located at each of one or more of the light sources is further configured to generate a second switch-off signal as at least one of a non-visible light optical signal, a radio frequency signal, and an acoustic signal, and wherein the remotely controllable switch located at each of one or more of the light sources is configured to wirelessly receive the first and/or second switch-off signals and switch off power to the corresponding light source in response to receiving the first and/or second switch-off signals. 12. The wind turbine according to claim 9 , wherein the switch-on signal is a first visible light switch-on signal, wherein visible light generated by at least one of the plurality of light sources is a second visible light switch-on signal, and wherein the remotely controllable switch located at each of the one or more light sources is configured to wirelessly receive the first and/or second visible light switch-on signals using a visible light photo-detector and switch on power to the corresponding light source in response to receiving the first and/or second switch-on signals. 13. The wind turbine according to claim 12 , wherein the remotely controllable switch is further configured to wirelessly sense whether a neighboring light source is switched off using the visible light photo-detector and to switch off power to the corresponding light source in response to sensing that the neighboring light source is switched off.