Method and system for communicating via light signals

The invention claimed is: 1. A system comprising: a plurality of first devices, each respective first device configured to transmit a low-frequency, LF, light signal comprising an identifier of the respective first device, and to transmit and/or receive a high-frequency, HF, light signal comprising data content; and a second device configured to receive a respective LF light signal from each of the first devices, and to transmit and/or receive a HF light signal from at least one of the first devices, wherein the second device has an adaptable receiving and/or transmitting direction for respectively receiving and/or transmitting the HF light signal, and wherein the second device comprises a controller configured to: based on the respective identifiers encoded in the respective LF light signals, determine a position of the second device relative to each of the first devices, and select one of the first devices; and based on said determination, adapt the receiving and/or transmitting direction of at least the HF light signal of the second device toward the selected first device and wherein the second device is configured to receive the LF light signal using a receiver having a wide receiving angle, and to receive the HF light signal using a receiver having a narrow receiving angle. 2. A system according to claim 1 , wherein the controller is configured to perform said selection by: selecting the first device that is nearest to the second device; and/or selecting the first device that is transmitting the respective LF light signal having the greatest received signal strength and/or the greatest signal-to-noise ratio. 3. A system according to claim 1 , wherein each first device is configured to transmit the LF light signal as a visible light signal or as an infrared light signal, and/or to transmit the HF light signal as a visible light signal or as an infrared light signal. 4. A system according to claim 1 , wherein at least one of: at least part of the second device is configured to move in space, and wherein the controller is configured to adapt the receiving and/or transmitting direction of the second device by causing said at least part of the second device to move in a direction toward the selected first device; the second device comprises an array of HF light signal receivers, each having a different direction for receiving HF light signals, and wherein the controller is configured to adapt the receiving direction of the second device by enabling a subset of the array of HF light signal receivers; the second device comprises an array of photodiodes, each photodiode comprising a different lens, and wherein the controller is configured to adapt the receiving direction of the second device by enabling only a subset of the array of photodiodes to receive HF light signals; and/or the second device comprises an array of HF light signal transmitters each having a different direction for transmitting a HF signal, and wherein the controller is configured to adapt the transmitting direction of the second device by enabling only a subset of transmitted HF light signals. 5. A system according to claim 1 , wherein the second device is configured to be connectable with a user device, and wherein the controller is configured to: (i) decode data content from a HF light communication signal received from the selected first device, and relay the decoded data content to the user device via a connection between the second device and the user device; and/or (ii) code data content receiving from the user device via the connection, and relay the coded data to the selected first device as a HF light communication signal. 6. A system according to claim 1 , wherein the second device comprises a visual indicator, and wherein the controller is configured to control the visual indicator to visually indicate, based on said determination, a direction in which to direct the receiving and/or transmitting direction toward the selected first device. 7. A system according to claim 1 , wherein each respective first device comprises a first transmitter configured to transmit the LF light signal, and a second transmitter to transmit the HF light signal, and wherein the first and second transmitters are co-located. 8. A system according to claim 1 , wherein each first device is configured to receive a light signal from the second device, wherein the second device is configured to transmit the light signal, and wherein the light signal comprises at least one of: a HF light signal comprising data content; and/or a LF light signal comprising a wake-up signal, and wherein in response to receiving the wake-up signal, each of the first devices is configured to transmit the HF light signal. 9. A system according to claim 1 , wherein the controller is configured to, after adapting the receiving and/or transmitting direction of the receiving device: adapt a receiving opening angle of the receiving device, thereby adapting an extent of a field-of-view of the second device, in order to reduce interference of the HF light signal transmitted by the selected device from HF light signals transmitted by non-selected devices; and/or adapt a transmitting opening angle of the receiving device, thereby adapting a beam width of the second device, in order reduce interference at the non-selected first devices by the HF light signal transmitted by the second device. 10. A system according to claim 1 , wherein the controller is configured to: detect that the second device has changed position; determine an updated position of the second device relative to each of the first devices and select an updated first device; and based on said determination of the updated position, adapt the receiving and/or transmitting direction of the second device toward the updated first device. 11. A system according to claim 10 , wherein the controller is configured to perform said detection by: determining the updated position based on the respective identifiers encoded in the respective LF light signals received from each of the first devices; and/or receiving positional information from one or more accelerometers housed in the second device. 12. A receiving device comprising: a transceiver configured to receive a respective low-frequency, LF, light signal from a plurality of transmitting devices, wherein the LF light signal received from each transmitting device comprises a respective identifier of the transmitting device, and to receive and/or transmit a high-frequency, HF, light signal comprising data content, wherein the receiving device has an adaptable receiving and/or transmitting direction for respectively receiving and/or transmitting the HF light signal; and a controller configured to: based on the respective identifiers encoded in the respective LF light signals, determine a position of the receiving device relative to each of the transmitting devices, and select one of the first devices; and based on said determination, adapt the receiving and/or transmitting direction of at least the HF light signal of the receiving device toward the selected transmitting device and wherein the receiving device is configured to receive the LF light signal using a receiver having a wide receiving angle, and to receive the HF light signal using a receiver having a narrow receiving angle. 13. A method comprising: receiving, from each of a plurality of first devices, a respective low-frequency, LF, light signal comprising an identifier of a respective first device; based on the respective identifiers encoded in the respective LF light signals, determining a position of a second device relative to each of the fi