DE102008037023A1 - Receiver for activating battery operated unit of information transmission system during e.g. voice communication for household, has evaluation unit producing evaluation that corresponds to light signal of signal characteristic - Google Patents

Abstract

The receiver (EE) has a light receiver (LE) i.e. solar cell, for detecting a light signal (L1) and converting the light signal into an electrical signal for an energy supply of an evaluation unit (AE). The evaluation unit for evaluating the light signal and activating a battery operated unit (G), produces an evaluation that corresponds to the light signal of a signal characteristic (E1). The receiver receives the light signal in one of optical spectral regions (S1, S2) that are provided between a transmitter (SE) and the receiver for transmission of data i.e. voice data. Independent claims are also included for the following: (1) a device including a receiver and a transmitter (2) a receiving method for activating a battery operated unit (3) a transmitting method for activating a battery operated unit.

Description

The The invention relates to a method, a transmission method, a reception method, a device, a transmitting unit and a receiving unit for Activate at least one device.

As part of the current discussion on CO2 savings, new devices are being offered on the market that save energy, for example by means of a low-power standby mode. Intelligent systems for controlling electrical appliances in residential or corporate buildings have also been marketed for some time, reducing, inter alia, household power consumption. One of these system will be under a name digital stream, see www.digitalstrom.org marketed, in which a control of electrical equipment through the existing power grid in the residential or corporate building is feasible.

Next the saving of power consumption in devices in private Household should also power devices in the industrial environment save on. So it is desirable that devices, in the optical data transmission, such as routers or optical receivers, are used energy efficient work. In particular, the power consumption in standby mode be as low as possible.

It The object of the following invention is methods and devices indicating the operation of equipment, ie. H. components an optical communication system with a possible enable low energy consumption in each standby mode.

These Task is solved by the independent claims 1, 9, 14, 15, 22 and 27 solved. The dependent ones Claims represent developments of the invention.

• – eine Lichtempfangseinheit zum Detektieren des ersten Lichtsignals und zum Umwandeln des ersten Lichtsignals in ein elektrisches Signal zur Energieversorgung einer Auswerteinheit;
• – die Auswerteeinheit zum Auswerten des ersten Lichtsignals und zum Aktivieren des Geräts, falls die Auswertung ergibt, dass das erste Lichtsignal einer vorgebbaren ersten Signaleigenschaft entspricht.

The invention relates to a receiving unit for activating at least one device, wherein the receiving unit receives a first light signal in a first optical spectral range, wherein the first optical spectral range and a second optical spectral range of a second light signal, for transmitting data, in particular voice data, between a Transmitting unit and the receiving unit is used, are different,
the receiving unit comprises the following units:

• A light receiving unit for detecting the first light signal and for converting the first light signal into an electrical signal for powering an evaluation unit;
• - The evaluation unit for evaluating the first light signal and for activating the device, if the evaluation shows that the first light signal corresponds to a predetermined first signal characteristic.

The Receiving unit shows the advantage that the device, the in stand-by mode, without external power supply activated can be. By converting the in the first light signal Energy contained in electrical energy in the form of electrical energy Signals can be both a power supply required for activation Ensures units of the receiving unit as well as a Evaluation and activation of the device. Thus, during stand-by operation only a small or no energy consumed. Furthermore, all variants of the present invention also has the advantage that the respective method or receiving or transmitting unit for a battery-operated Device, z. B. used in a sensor network used can be, because all variants the electricity or energy consumption significantly lower the device. The transfer of Data may be in the free space and / or by means of a transmission medium, z. As a polymer fiber, take place.

Preferably the evaluation unit evaluates the electrical signal as a representative for the first light signal, resulting in a simple implementation is achieved.

Further the receiving unit can be a wavelength selection unit, in particular designed as a chromatic beam splitter or filter bank, for Disconnecting the first light signal and the second light signal due the first optical spectral range and the second optical Have a spectral range, whereby a secure separation of the first is reached by the second light signal. This reduces interference of the second light signal in the first light signal.

In an optional extension of the invention comprises the first light signal at least two pieces of information. The evaluation unit evaluates this the respective information units, using a respective information unit, a respective device and / or a respective device state of a device individually can be activated. With the help of information units can several devices can be activated separately in a simple way. Additionally or alternatively, different Device states of a device, such as Switching the device on or off or switching it on in two different operating modes are activated. Under device state In this context, it is generally understood that the device can be in different operating modes.

The first light signal can have at least two partial optical spectral ranges within the first optical spectral range, wherein the respective optical partial spectral range is a respective one gen information unit is assigned. In this case, a simple implementation of the at least two information units is possible. Alternatively or additionally, the first light signal within the first optical spectral range can have at least two time-sequential signal sections, wherein the respective signal section is assigned to a respective information unit. In this case, the reception method can be realized in a simple manner.

Further Additionally or alternatively, the information units the first light signal by means of a modulation, in particular by means of a pulse-code modulation, in which belonging to the first light signal be modulated optical spectral range. This is a simple one Realization of the information units by means of modulation achievable.

In a development of the invention evaluates the evaluation unit Evaluation of the first light signal from the second light signal, and, if the evaluations show that the first light signal of the first Signal property and the second light signal at least one second signal property, this is due to the first and / or second light signal signaled device activated. In This development is using the first light signal a Energy supply of the evaluation unit achieved and with the help of second light signal a concrete selection and activation of the device signaled. In addition, with this training also complex signaling are performed, such. B. presetting various operating modes of the device after activation.

Preferably is used as a light receiving unit, a solar cell, the cost and operating conditions of the receiving unit, such as amount of generated Energy medium Selection of the area of the solar cell or reaction time to enable the device, is customizable.

Further Part of the invention is a transmitting unit for activating at least a device in which the transmitting unit transmits a first light signal, having a first signal property, in a first optical Spectral range transmits, with the first optical spectral range and a second optical spectral range of a second light signal, that for transmitting data, in particular voice data, can be used between the transmitting unit and a receiving unit, are different, and wherein the first light signal for converting in an electrical signal for power supply to an evaluation of the Receiving unit and signaling the device to be activated is provided using the electrical signal.

The Transmitter unit enables energy-efficient use the receiving unit.

Preferably at least adds the transmitting unit in the first light signal two information units, wherein based on the respective information units a respective device and / or a respective device state a device can be activated individually. This allows more than one device can be activated individually. moreover the transmitting unit can receive the first light signal within the first optical spectral range with at least two partial optical spectral ranges generate, wherein the respective optical partial spectral range of a associated with each information unit. This extension allows the receiving unit, the information units in easy to detect. Additionally or alternatively may be the first light signal within the first optical spectral range have at least two temporally successive signal sections, wherein the respective signal portion of a respective information unit assigned. As a result, the respective information unit be encoded in a simple manner in the first light signal

additionally or alternatively, the transmitting unit modulates the information units the first light signal by means of a modulation, in particular by means of a pulse-code modulation, in which belonging to the first light signal first optical spectral range. This type of coding is advantageous because the receiving unit, the information units with low technical Can demodulate effort.

The Transmitting unit is further configured to transmit the second light signal temporally after the transmission of the first light signal, wherein the second light signal has at least one second signal property, and wherein that due to the first and / or second light signal signaled device is activated. In this training is using the first light signal, a power supply of the Evaluation unit reached and with the help of the second light signal a concrete selection and activation of the device signals. In addition, with this training, even complex signaling be performed, such. B. presetting different Operating modes of the device after activation.

The The invention further relates to a device comprising the receiving unit according to one of the above statements and the transmitting unit according to one of the above embodiments includes.

• – Detektieren des ersten Lichtsignals und Umwandeln des ersten Lichtsignals in ein elektrisches Signal zur Energieversorgung einer Auswerteinheit;
• – Auswerten des ersten Lichtsignals und Aktivieren des Geräts, falls die Auswertung ergibt, dass das erste Lichtsignal einer vorgebbaren ersten Signaleigenschaft entspricht, wobei das Auswerten und das Aktivieren durch die Auswerteeinheit durchgeführt werden.

In addition, a receiving method for activating at least one device is part of the invention, in which a first optical spectral range of a first light signal and a second optical spectral range of a second light signal for transmitting data, in particular voice data, between a transmitting unit and a receiving unit can be used, are different,
where the following steps are performed:

• - Detecting the first light signal and converting the first light signal into an electrical signal for powering an evaluation unit;
• - Evaluating the first light signal and activating the device, if the evaluation shows that the first light signal corresponds to a predeterminable first signal property, wherein the evaluation and the activation are performed by the evaluation unit.

The Receiving method shows the advantage that the device that in stand-by mode, without external power supply activated can be. By converting the in the first light signal Energy contained in electrical energy in the form of electrical energy Signals can be both a power supply required for activation Ensures units of the receiving unit as well as a Evaluation and activation of the device. Thus, during stand-by operation no energy or consumed only a very small amount of energy.

Preferably the evaluation unit evaluates the electrical signal as a representative for the first light signal, resulting in a simple implementation is achieved.

Further the reception method can be a wavelength selection unit, especially designed as a chromatic beam splitter or filter bank, for separating the first light signal and the second light signal due to the first optical spectral range and the second optical Use spectral range, thereby providing a safe separation of the first is reached by the second light signal. This reduces interference of the second light signal in the first light signal.

In an extension of the reception method has the first light signal at least two information units and the respective information units are evaluated, based on the respective information unit a respective device and / or a respective device state of a device is activated individually. With the help of Information units can have multiple devices separately be activated in a simple manner. So can the first light signal within of the first optical spectral range at least two partial optical spectral ranges , wherein the respective partial optical spectral range of a associated with each information unit. Here is one easy implementation of the at least two pieces of information possible. In addition or optionally, the first light signal within the first optical spectral range having at least two temporally successive signal sections are evaluated, wherein the respective signal portion assigned to a respective information unit becomes. This approach shows the advantage that over the use of optical partial spectral ranges a higher Robustness against transmission errors achievable is, as per information unit a larger optical Bandwidth is available.

Further Additionally or alternatively, the information units the first light signal by means of a modulation, in particular by means of a pulse-code modulation, in which belonging to the first light signal be modulated optical spectral range. This is a simple one Realization of the information units by means of modulation achievable.

Preferably after evaluation of the first light signal, the second light signal evaluates, and, if the evaluations show that the first light signal the first signal property and the second light signal at least correspond to a second signal property, due to the first and / or second light signal signaled device activated. In This development is using the first light signal a Energy supply of the evaluation unit achieved and with the help of second light signal a concrete selection and activation of the device signaled. In addition, with this training also complex signaling are performed, such. B. presetting various operating modes of the device after activation.

Of Furthermore, the invention comprises a transmission method for activating at least one device in which a first light signal, which has a first signal property, in a first optical spectral range is transmitted, wherein the first optical spectral range and a second optical spectral range of a second light signal, the for transmitting data, in particular voice data, can be used between the transmitting unit and a receiving unit, are different, and wherein the first light signal for converting in an electrical signal for power supply to an evaluation of the Receiving unit and for signaling the device to be activated is provided using the electrical signal.

The Transmitting method enables energy-efficient use the receiving unit or the receiving method.

Preferably, the transmission method inserts at least two information units into the first light signal, wherein a respective device and / or a respective device state of a device can be individually activated on the basis of the respective information units. This allows more than one device to be activated individually. In addition, the Sendeverfah Ren generate the first light signal within the first optical spectral range with at least two partial optical spectral regions, wherein the respective optical partial spectral range is assigned to a respective information unit. This extension allows the receiving unit or the receiving method to detect the information units in a simple manner. Furthermore or alternatively, the first light signal can be generated within the first optical spectral range having at least two temporally successive signal sections, wherein the respective signal section is assigned to a respective information unit. This approach has the advantage that compared to the use of the partial optical spectral regions, a higher robustness to transmission errors can be achieved, since a larger optical bandwidth is available per information unit.

additionally or alternatively, the transmission method modulates the information units the first light signal by means of a modulation, in particular by means of a pulse-code modulation, in which belonging to the first light signal first optical spectral range. This type of coding is advantageous because the receiving method the information units with low technical Can demodulate effort.

Becomes the second light signal in time after transmitting the sent first light signal, wherein the second light signal of a second signal property and that due to the first and / or second light signal signaled device is activated. In this development, with the aid of the first light signal a Energy supply of the evaluation unit achieved and with the help of second light signal a concrete selection and activation of the device signaled. In addition, with this training also complex signaling are performed, such. B. presetting various operating modes of the device after activation.

After all Part of the invention is a method for activating at least one Device, the receiving method according to a the above embodiments and the transmission method according to one of has the above statements.

The Invention and its development will be with reference to the following figures explained in more detail. Show it

1 a first embodiment for activating a device;

2 a second embodiment for activating two devices;

3 a third embodiment for activating two devices by means of a first and second light signal;

4 a flowchart for describing a method for activating at least one device G.

elements with the same function and mode of action are in the figures with provided the same reference numerals.

The invention and its developments are based on an embodiment of the field of optical data transmission by means of glass fiber according to 1 explained in more detail.

1 shows a device V comprising a transmitting unit SE and a receiving unit EE. The transmitting unit and the receiving unit are connected via a fiber LL for data transmission. The data may include voice, video, fax data or data coded in accordance with a standard LAN (Local Area Network). The fiber is, for example, designed as a glass fiber or polymer fiber. In the 1 Fiber shown is part of a long distance optical network for transmitting voice signals for telephone connections. The fiber has a transparency range of 400 to 2000 nm. For transmission of the speech signals by means of a second light signal L2, a second optical spectral range S2 of 1260 to 1675 nm of the fiber is occupied. The second light signal is transmitted from the transmitting unit via the fiber to the receiving unit, evaluated there and as an electrical signal to a device G, z. B. a voice exchange unit, forwarded for evaluation. The processing of the second light signal is not the subject of the present invention and is therefore in the 1 not shown in detail.

To certain times, eg. B. between 1 and 5 clock early only to a very limited extent the data transmission instead of. Therefore, the transmitting unit signals to the receiving unit via a special control information transmitted by means of the second light signal is that the receiving unit from now on in a standby mode, d. H. a sleep mode, to be operated. The receiving unit is thus in standby mode.

If the transmission of voice messages between the transmitting unit and the receiving unit is to be resumed, the transmitting unit transmits a first light signal L1 in a first optical spectral range S1, between 400 and 1100 nm, via the fiber LL. It should be noted that the optical spectral ranges of the first and second light signals are different in order to avoid mutual signal interference. For the separation of the first and second light signal ver the Emp Capture unit via a wavelength selection unit TE, in particular as a chromatic beam splitter or filter bank formed, which divides the incoming light through the fiber wave selectively in predetermined optical spectral ranges, ie in the first and second optical spectral range S1, S2. Thus, only the first and the second light signal occur at the outputs of the wavelength selection unit. The first light signal is supplied to a light receiving unit LE, which converts the first light signal into an electrical signal ES. The light receiving unit is, for example, designed as a photocell. Depending on the quality of the beam splitter unit, a material and diameter of the fiber and the first optical spectral range can be transferred a few milliwatts to watts of optical energy, which is convertible in the order of 10-20% in the electrical energy. This is known, for example, from a document [1].

The electrical energy obtained by the light receiving unit LE in the form of the electrical signal ES is an evaluation unit AE supplied as an electrical power supply. The evaluation unit can the electrical energy at least partially, for example. By means of capacitors save or buffer. The evaluation unit checks, whether the first light signal represented by the electrical signal corresponds to a predetermined first signal property E1. First Signal property is used, for example, a period in which the electrical Signal and thus the first light signal can be measured, for example exceed a predefinable voltage level. The first Signal property is, for example, E1> = 50 ms (ms - milliseconds). This means that the evaluation unit the characteristic of the electrical signal and thus of the first Light signal checked to see if this for at least 50 ms is present. If this is the case, it recognizes Evaluation unit that wakes the device from standby mode shall be. The evaluation unit generates a wake-up signal for this purpose AS, which, for example, an external power supply of the device activated.

To This is the activation of the device from standby mode Device ready for operation via the second light signal Receive voice signals.

It is thus possible the receiving unit EE using only passive Create components. In addition, the receiving unit requires and the device during standby mode none external energy supply.

In one extension, several devices, for example two devices G1, G2, can be individually awakened from their respective standby mode. This can be realized with different variants. In a first variant, see 2 , the first optical spectral range of the first light signal is split into two partial optical spectral ranges S11, S12. If the first light signal is transmitted only for the first partial optical spectral range, only the first device G1 is woken up from its standby mode. When we transmit the first light signal only in the second partial spectral optical range, only the second G2 device is woken up from its standby mode. If the first light signal is transmitted in the first and second optical partial spectral range, then both devices G1, G2 are activated, ie woken up from their respective standby mode.

In an alternative embodiment, the technical Implementation to wake up two or more devices used for example. A device in two different To awaken device states. For example one of the device states necessary to voice data receive, with the other of the device states receiving data that encodes using the LAN protocol are allowed. It is also possible several devices each with one or more device states to activate.

In a second variant, see 3 , Time delayed after the transmission of the first light signal, one or more information signals I1, I2 by means of the second light signal from the transmitting unit to the receiving unit sent. First, analogously to the description according to 1 the first light signal or the electrical signal is checked on the basis of the first signal property E1 by the evaluation unit. In addition, at least one of the information signals I1, I2 is extracted from the second light signal and compared with a second signal property E2. If the first light signal corresponds to the first signal property and the information signal I1 corresponds to the second signal property, the device signaled by the information signal is activated from its standby mode as a function of the information signal. If both information signals I1, I2 have the respective second signal property, the devices G1 and G2 are activated by the respective wake-up signals AS from their respective standby mode.

In a third variant (not shown in one of the figures), an activation signal is modulated onto the first light signal, for example by means of pulse code modulation. In this case, the electrical signal for supplying the analysis unit with energy is obtained from the first light signal L1 as well as the waveform of the first light signal or the electrical signal ES compared with the first and the second signal property E1, E2. If the first signal property E1 matches the first light signal or the electrical signal, the first device G1 is activated by means of the wake-up signal AS, when the second signals i are detected In the first light signal or the electrical signal, the second signal is woken up by its wake-up signal.

ever upon request to a response time of the receiving unit to activate of a respective device, the light receiving unit can be varied become. A larger solar cell is sluggish as a small area. Thus, by choosing the size the solar cell, the reaction time of the receiving unit depending on the requirement be varied.

The above and below versions and variants can be combined and executed as desired.

The Transmitting unit SE is further adapted to transmit data in the second optical spectral range by means of the second light signal, from a transmission unit UE. The Transmitting unit generates the first and second light signals according to the above Executions, whereby the data to be transferred of the second light signal are coupled into the fiber. Transmission unit UE is, for example, a video or voice server of the video or voice messages to transmit to the receiving unit.

The Device comprising the transmitting and receiving unit, can in a from the transmission unit UE, the fiber LL and the device G existing transmission line later to get integrated.

Further the transmitting unit can independently at one or more Activate the standby mode if, for example, via a longer period no data for the respective Device is to be transmitted. Upon arrival of data at the transmitting unit, this can off the relevant device wake up its standby mode and then transfer the data over pass on the fiber. It is advisable to that the transmitting unit via a memory unit SP for Intermediate data.

In addition to the device V is also a method for activating at least one device G part of the invention. The method is based on a flow chart according to 4 explained in more detail. The following steps are performed:

Step STA:

In This step starts the flowchart. It follows a step T1.

Step T1:

in the Step T1 sends the transmitting unit SE a first light signal L1, wherein the first light signal L1 and one for a data transmission used light signal L2 in different optical spectral ranges S1, S2 are. The transmission unit SE transmits the first light signal by means of the light guide, d. H. the fiber, LL to the receiving unit EE. Next, a step T2 is passed through.

Step T2:

in this connection the light receiving unit LE receives the first light signal L1 and convert this into electrical energy in the form of the electric Signals ES around. The electrical signal serves as a power supply the evaluation unit and others to its characteristic the evaluation unit analyzed. In the following, step T3 is run through.

Step T3:

in this connection the first light signal is represented by the evaluation unit checked by the electrical signal, whether it corresponds to the first signal property E1. For example it is checked if the light intensity of the first Light signal reaches or exceeds a predetermined threshold and Furthermore, whether the first light signal for at least a period of time, for example, 2 seconds, is detected. Both the determination the threshold for light intensity as well the determination of the time duration are components of the first signal property E1.

Complies now the first light signal L1 of the first signal property E1, so the flowchart continues in path J and next Step T4 is executed. Otherwise, with step END in the path N continued.

Step T4:

In This step, a control signal AS is generated and the device G supplied to its activation. For example, pressed the activation signal AS is a relay with which a power supply of the device G is activated. The activation signal AS is for example, kept active for 5 seconds before it is switched off again. After performing the step T4, the step END is executed next.

Step END:

in the Step END ends the flowchart.

In the above embodiments, among other things, the information units I1, I2 were coded by means of two partial optical spectral ranges. In an additional or alternative embodiment, these may also be consecutive in time in the first Light signal are coded, ie, so to speak, according to the time-multiplexing technology.

Next the device V and the method, the invention also includes the Receiving unit EE. The receiving unit EE comprises the light receiving unit LE for detecting the first light signal, wherein the first light signal and one used for data transmission second light signal L2 in different optical spectral ranges S1, S2, and for converting the first light signal L1 into electrical Energy as an electrical signal and the evaluation unit AE for evaluation the first light signal and to activate the device G, if the evaluation shows that the first light signal L1 of the predeterminable first signal property E1 corresponds. Furthermore, the receiving unit EE be designed to one or more of the previously presented Implement variants to realize. Both the device V and the receiving unit EE and the transmitting unit SE can in software, hardware or in a combination of software and hardware be implemented.

When Areas of application of the present invention is, for example an optical long-distance network for the transmission of data, such as language or Internet data or in the field of optical data transmission for medical data, used.

Literature:

• [1] G. Böttger et al: "Optically Powered Video Camera Link", Proc. of 33th European Conf. Opt. Commun. (ECOC '07), Berlin, Germany, September 16-20, 2007

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - www.digitalstrom.org [0002]

Claims (31)

Receiving unit (EE) for activating at least one device (G), characterized in that the receiving unit (EE) receives a first light signal (L1) in a first optical spectral range (S1), wherein the first optical spectral range (S1) and a second optical Spectral range (S2) of a second light signal (L2), which is used for transmitting data, in particular voice data, between a transmitting unit (SE) and the receiving unit (EE) are different, the receiving unit (EE) comprising the following units: - a light receiving unit (LE) for detecting the first light signal (L1) and for converting the first light signal (L1) into an electrical signal (ES) for supplying energy to an evaluation unit (AE); - The evaluation unit (AE) for evaluating the first light signal (L1) and for activating the device (G), if the evaluation shows that the first light signal (L1) corresponds to a vorgebaren first signal characteristic (E1). Receiving unit (EE) according to claim 1, characterized that the evaluation unit (AE) the electrical signal (ES) as a representative for the first light signal (L1) evaluates. Receiving unit (EE) according to claim 1 or 2, characterized characterized in that the receiving unit (EE) further comprises a wavelength selection unit (TE), especially designed as a chromatic beam splitter or filter bank, for separating the first light signal (L1) and the second light signal (L2) due to the first optical spectral range (S1) and the second optical spectral range (S2). Receiving unit (EE) according to one of the preceding Claims, characterized in that the first Light signal (L1) has at least two information units (I1, I2), the Evaluation unit (AE) evaluates the respective information units, wherein with the aid of a respective information unit (I1, I2) a respective device (G1, G2) and / or a respective device state of a device (G1) can be activated individually. Receiving unit (EE) according to Claim 4, characterized in that the first light signal (L1) is within the first optical spectral range (S1) has at least two partial optical spectral regions (S11, S12), wherein the respective partial optical spectral range (S11) of a respective Information unit (I1) is assigned. Receiving unit (EE) according to claim 4 or 5, characterized characterized in that the first light signal (L1) within the first optical spectral range (S1) at least two temporally successive Signal sections, wherein the respective signal portion of a associated with each information unit (I1). Receiving unit (EE) according to one of the claims 4 to 6, characterized in that the information units (I1, I2) of the first light signal (L1) by means of a modulation, in particular by means of a pulse-code modulation in which the first Light signal belonging to the spectral optical spectrum (S1) modulated are. Receiving unit (EE) according to one of the preceding Claims, characterized in that the evaluation unit (AE) after evaluation of the first light signal (L1), the second light signal (L2) evaluates, and, if the evaluations show that the first Light signal (L1) of the first signal characteristic (E1) and the second Light signal (L2) of at least one second signal property (E2) correspond, due to the first and / or second light signal (L1, L2) signaled device (G, G1, G2) is activated. Receiving unit (EE) according to one of the preceding Claims, characterized in that the light receiving unit (LE) is designed as a solar cell. Transmitting unit (SE) for activating at least one Device (G), characterized in that the Transmitting unit (SE), a first light signal (L1) having a first signal property (E1), in a first optical spectral range (S1) transmits, in which the first optical spectral range (S1) and a second optical Spectral range (S2) of a second light signal (L2), which is to transmit of data, in particular voice data, between the transmitting unit (SE) and a receiving unit (EE) can be used, different are, wherein the first light signal (L1) for converting into an electrical Signal (ES) for supplying energy to an evaluation unit (AE) of the Receiving unit (EE) and for signaling the to be activated Device (G) using the electrical signal (ES) is provided. Transmitting unit (SE) according to claim 10, characterized in that in that the transmitting unit (SE) in the first light signal (L1) at least two information units (I1, I2) inserts, using the respective information units a respective device (G1, G2) and / or a respective device state of a device (G1) can be activated individually. Transmitting unit (SE) according to claim 11, since characterized in that the transmitting unit (SE) generates the first light signal (L1) within the first optical spectral range (S1) with at least two partial optical spectral ranges (S11, S12), the respective optical partial spectral range (S11) being associated with a respective information unit (I1) is. Transmitting unit (SE) according to claim 11 or 12, characterized characterized in that the first light signal (L1) within the first optical spectral range (S1) at least two temporally successive Signal sections, wherein the respective signal portion of a associated with each information unit (I1). Transmitting unit (SE) according to one of the claims Claim 11 to 13, characterized in that the transmitting unit (SE) the information units of the first light signal (L1) by means of a modulation, in particular by means of a pulse-code modulation, in the first optical signal associated with the first light signal (L1) Spectral range (S1) modulated. Transmitting unit (SE) according to one of the claims 10 to 14, characterized in that the transmitting unit (SE) further configured to transmit the second light signal (L2) in time after transmitting the first light signal (L1), wherein the second light signal (L2) at least one second signal property (E2), wherein the due to the first and / or second light signal (L1, L2) signaled device (G1) is activated. Device (V), characterized in that the Device (V) the receiving unit (EE) according to one of the claims 1 to 9 and the transmitting unit (SE) according to one of the claims 10 to 14. Receiving method for activating at least one Device (G), characterized in that one first optical spectral range (S1) of a first light signal (L1) and a second optical spectral range (S2) of a second Light signal (L2), which is used to transfer data, in particular of voice data, between a transmitting unit (SE) and a receiving unit (EE) can be used, are different, at the following Steps to be performed: - Detect of the first light signal (L1) and converting the first light signal (L1) into an electrical signal (ES) to power a Evaluation unit (AE); - Evaluation of the first light signal (L1) and activate the device (G) if the evaluation shows that the first light signal (L1) of a vorgebaren first Signal property (E1), where the evaluation and the activation be performed by the evaluation unit (AE). Receiving method according to claim 17, characterized in that that the electrical signal (ES) as a representative of the first light signal (L1) is evaluated. Receiving method according to claim 17 or 18, characterized characterized in that the first light signal (L1) and the second light signal (L2) due to the first optical spectral range (S1) and the second optical spectral range (S2) by means of a wavelength selection unit (TE), in particular as a chromatic beam splitter or filter bank trained, be split. Receiving method according to one of the claims 17 to 19, characterized in that the first light signal (L1) has at least two information units (I1, I2), the respective information units are evaluated, based on the respective information unit (I1, I2) a respective device (G1, G2) and / or a respective device state of a device (G1) is activated individually. Receiving method according to claim 20, characterized in that a respective partial optical spectral range (S11) of the first Light signal (L1) is evaluated, with the respective optical Partial spectral range (S11) assigned to a respective information unit is. Receiving method according to one of the claims 20 or 21, characterized in that the first light signal (L1) within the first optical spectral range (S1) evaluated at least two temporally successive signal sections is, wherein the respective signal portion of a respective information unit (I1) is assigned. Receiving method according to one of the claims 20 to 22, characterized in that the on the first light signal (L1) modulated information units (I1, I2), in particular modulated by means of a pulse-code modulation, for evaluation by demodulation of the first light signal (L1) are obtained. Receiving method according to one of the claims 17 to 23, characterized in that after evaluation of the first Light signal (L1), the second light signal (L2) is evaluated, and, if the evaluations show that the first light signal (L1) the first signal property (E1) and the second light signal (L2) correspond to at least one second signal property (E2), the device signaled on the basis of the first and / or second light signal (L1, L2) (G1) is activated. Transmission method for activating at least a device (G), characterized in that a first light signal (L1) having a first signal characteristic (E1) is transmitted in a first optical spectral range (S1), the first optical spectral range (S1) and a second optical spectral range (S2) of a second light signal (L2), which is used for transmitting data, in particular of voice data, between the transmitting unit (SE) and a receiving unit (EE) are different, wherein the first light signal (L1) for converting into an electrical Signal (ES) for supplying power to an evaluation unit (AE) of the receiving unit (EE) and for signaling the device to be activated (G) using the electrical signal (ES) is provided. Transmitting method according to Claim 25, characterized in that in the first light signal (L1) at least two information units (I1, I2) are inserted, using the respective Information units (I1, I2) a respective device (G1, G2) and / or a respective device state of a device (G1) individually activatable. Transmitting method according to Claim 26, characterized that the first light signal (L1) within the first optical spectral range (S1) with at least two partial optical spectral regions (S11, S12) is generated, wherein the respective partial optical spectral range (S11) associated with a respective information unit (I1). Transmitting method according to one of Claims 25 or 27, characterized in that the first light signal (L1) within the first optical spectral range (S1) generates at least two temporally successive signal sections is, wherein the respective signal portion of a respective information unit (I1) is assigned. Transmission method according to one of Claims 26 to 28, characterized in that the information units of first light signal (L1) by means of a modulation, in particular by means of a pulse-code modulation in which the first light signal (L1) belonging first optical spectral range (S1) modulated become. Transmitting method according to one of Claims 25 to 29, characterized in that the second light signal (L2) temporally after the transmission of the first light signal (L1) is transmitted, wherein the second light signal (L2) of a second signal property (E2) and that due to the first and / or second light signal (L1, L2) signaled device (G1) is activated. Method for activating at least one device (G), characterized in that the method is the receiving method according to any one of claims 17 to 24 and the transmission method according to one of the claims 25 to 30.