EP3359916A1 - Radio-controlled system for data transmission - Google Patents

Abstract

The invention relates to a radio-controlled system for data transmission, which has a transmitting unit which transmits electromagnetic radio waves to a receiving unit by means of terrestrial transmission, wherein the receiving unit can be activated when the electromagnetic radio waves arrive, wherein the transmitting unit transmits a control notification or information to the receiving unit via the radio waves, such that a processing unit arranged on the receiving unit goes through a change of state, wherein the receiving unit can be deactivated after the end of the transfer of the electromagnetic radio waves.

Description

 Radio-controlled system for data transmission.

The invention relates to a radio-controlled system for data transmission, in particular a radio-controlled system with a transmitting unit for emitting electromagnetic waves and a receiving unit for receiving the electromagnetic waves.

It is well known that data from sensors can be picked up by means of suitable sensor units. In this case, the sensor units may be part of a receiving unit which is set up to receive electromagnetic waves which are emitted by a transmitting unit and contain signals which can be used both to configure the sensor unit arranged on the receiving unit and to trigger the actual measuring operation. The data thus acquired can then be stored on the receiving unit, so that they are available for further processing steps.

From the state of the art, so-called transmitter-receiver systems for the contactless identification of objects by means of radio waves are known, which are typically referred to in the English language as RFID systems. Such systems include a transponder located on the object and a reader for reading the data stored on the transponder. The transponder is supplied with energy by the alternating magnetic fields generated by the reader. For longer ranges, active transponders with their own power supply are typically used.

Previously known systems therefore have the disadvantage that they either allow only a transmission with a short range or Active receivers need, but often can be connected in hard to reach areas only by great effort to a power supply. There is therefore a need in the art to develop known radio controlled systems so that such limitations can be circumvented.

It is therefore an object of the invention to provide a radio-controlled system for data transmission, which manages with the least possible infrastructure, so that the installation is less time consuming and causes only low costs.

This object is solved by the features of patent claim 1. Further advantageous embodiments of the invention are the subject of the dependent claims. These can be combined in a technologically meaningful way. The description, in particular in conjunction with the drawing, additionally characterizes and specifies the invention. According to the invention, a radio-controlled system for data transmission is provided, which has a transmitting unit which transmits electromagnetic radio waves to a receiving unit by means of terrestrial transmission, wherein the receiving unit can be activated upon arrival of the electromagnetic radio waves, wherein the transmitting unit transmits information or a control message to the receiving unit sent via the radio waves, so that a processing unit arranged on the receiving unit passes through a state change, wherein after the end of the transmission of the electromagnetic radio waves, the receiving unit can be deactivated. Accordingly, the receiving unit is activated only when a signal is emitted by the transmitting unit or when the signal emitted by the transmitting unit is also intended for the receiving unit. The radio-controlled system according to the invention is therefore energy-saving, requires no complex infrastructure measures and can also be used in remote areas, without causing high installation costs. The control message can be both data packets for further processing on the processing unit and control signals for initiating a program sequence on the processing unit.

According to one embodiment of the invention, the processing unit comprises a sensor unit, a demodulator or a calculation unit.

The processing unit may associate the transmitted data of the control message with other external quantities determined by a sensor unit. Likewise, further radio signals can be received by means of a demodulator or generally further processed by means of a calculation unit. According to a further embodiment of the invention, the sensor unit arranged on the receiving unit receives correction signals from the transmitting unit in order to generate location information by means of a differential GPS method. Accordingly, it is possible to obtain accurate location information on the receiving unit by further processing the GPS signals received from the sensor unit with the correction data. Thus, the receiving unit may perform any additional control tasks using the accurate location information. According to a further embodiment of the invention, the control message is directed to an actuator which effects a mechanical movement which is implemented either by the receiving unit as a whole or other components located thereon.

Consequently, it is possible for the receiving unit of the radio-controlled system according to the invention to move, for example, as a whole in the centimeter range towards a control message, in order to carry out any applicable control tasks at another position. In this case, the precise location information already mentioned above can additionally be used for a precise sequence of the control.

According to another embodiment, the sensor unit uses the control message as control data.

Accordingly, the control message is further processed by the sensor unit, so that the receiving unit is placed in a different state to process any additional control tasks based on the control message. According to a further embodiment of the invention, the transmitting unit and the receiving unit are designed for the frequencies FM, DVB-T2, DAB, DAB +, MW and / or LW and / or for DRM transmissions.

The transmission of the radio waves can take place via AM transmitter or FM transmitter over a longer distance, so that even hard to reach facilities or more distant systems can reach the radio station there arranged receiving unit or can also perform a power supply. The transmission can be carried out in the MW range or LW range. The FM transmitter can do this similar to a DRM, DAB or DAB + transmitter to transmit control data or audio signals. The transmission of image information can be done via the standard DVB-T2. According to a further embodiment of the invention, a plurality of receiving units is provided, which are controllable by a transmitting unit.

Accordingly, a transmission of radio waves or data or control messages from a transmitter to a plurality of receiving units, each of which can perform the same or different tasks. The receiving units can process the same or different tasks in the sensor units or actuators by means of appropriate address coding or via the exact location information. According to a further embodiment of the invention, the sensor unit determines pressure, temperature, humidity or other environmental parameters on the receiving unit.

The radio-controlled system according to the invention can advantageously be used for measuring environmental parameters in an open field, in which case the self-sufficient energy supply is advantageous in particular, since thus no power supply lines have to be routed to the field. Fields of application in agriculture but also in other areas, such. As the weather observation or the like, are many.

It is particularly advantageous that the actuator forms part of an irrigation system. Accordingly, in particular in connection with the exact location information and the sensors for determining environmental parameters irrigation systems can be precisely controlled, in which case the actual situation can be incorporated locally in the delivery of water.

According to a further embodiment of the invention, the receiving unit is part of a means of transport for goods and / or passenger transport.

In this case, the receiving unit is coupled to the means of transport and receives general information, eg regarding traffic information or the like, about the transmitting unit. This general information is then linked to local information, for example, derived from a sensor unit, so that a central control can be linked via the transmitting unit with decentralized decisions. Thus, for example, the transmitting unit could instruct a transport process of a self-propelled means of transport while leaving the precise processing to the receiving unit, which determines the further sequence on the basis of additional and only locally available information, eg with regard to the traffic situation. According to a further embodiment of the invention, the transmitting unit transmits ambient and / or status information as a control message, which links the receiving unit with local control parameters. In this case, the receiving unit may be part of a power supply unit. Thus, the receiving units of one type can perform a distributed intelligent control in which the system provides general environmental or status information via the transmitting unit, while the receiving unit passes the data to a processor which then determines local control parameters, eg weather information, that provide decentralized energy units generate or store electricity or generally start up equipment.

According to a further embodiment of the invention, the energy supply of the receiving unit takes place via the electromagnetic radio waves.

The system according to the invention therefore does not require its own power supply, since the power supply takes place via the electromagnetic radio waves emitted by the receiving unit. Consequently, no standby power is required, so that the processing unit arranged on the receiving unit does not need its own power supply or separate power lines.

According to a further embodiment of the invention, the receiving unit has an interface to a mobile terminal.

While the previously described embodiments have provided a receiving unit which has a complete functionality in itself, it is now proposed to execute the receiving unit with an interface to a mobile terminal. This makes it possible to connect the receiving unit, for example, with a mobile phone or a tablet computer. The additional functionality provided on the mobile terminal concerns less the connection to communication networks but the provision of additional input options for controlling the receiving unit. For this purpose, for example, a corresponding application software can be installed on the mobile terminal, which transmits control signals via the interface to the receiving unit. The receiving unit in turn can transmit the signal received within the radio-controlled system to the mobile terminal. These are in particular audio signals the radio program, TV signals via digital terrestrial television and data signals, such. As correction data, text messages or the like. As an interface, both a wired and a wireless interface, for example in the form of a Bluetooth interface can be used.

In this case, the receiving unit can be configured with an internal power supply such that charging of the mobile terminal is possible. Alternatively, the receiving unit can be supplied via a power supply of the mobile terminal.

Accordingly, it is possible to read both the receiving unit via the already existing battery storage of the mobile terminal and in another embodiment to provide the mobile terminal via the internal power supply of the receiving unit with power. Consequently, depending on the size of the internal power supply or weight or space requirements at the receiving unit, the power supply is selected accordingly.

According to a further embodiment of the invention, the receiving unit is controllable via the mobile terminal. In this case, the signals received by the receiving unit can be forwarded to the mobile terminal.

Consequently, the signal to be displayed on the mobile terminal can be selected via the mobile terminal, since corresponding control signals are transmitted to the receiving unit via the interface. Thus, by means of the radio-controlled system according to the invention, for example, a representation of terrestrial radio transmissions can take place which would not be displayable on a mobile terminal due to the lack of a corresponding decoding device. According to a further embodiment of the invention, the receiving unit is part of the mobile terminal.

In the previous embodiments, the mobile terminal and the receiving unit have been described as separate devices. As miniaturization progresses, however, it would be possible to combine the functionality of both devices in one.

According to a further embodiment of the invention, the receiving unit has a connection for a bus system. In this case, an interface module can be arranged between the receiving unit and the terminal, wherein the signals supplied to the interface module are carried on to a further terminal. Instead of a self-sufficient processing of signals or forwarding to mobile devices, it may alternatively or additionally be provided to equip the receiving unit with a port for a bus system. In this case, a corresponding interface module can process internal data signals of the receiving unit and forward it to the bus system following its own protocol. Alternatively or additionally, however, it would be possible to already use a standardized protocol in the transmission to the interface module, so that the signal not processed by the interface module can be output via a further connection. Thus, for a user wishing to couple another utilization device to the bus system, there is a choice as to what type of signals should be processed at the port or at the remote port.

The receiving unit may be configured to receive DRM signals at a single adjustable frequency in the LW or MW range. Advantageously, the receiving unit is addressable via the received DRM signal and, in accordance with a predetermined value, forwards the possibly decoded received signal to the terminal for a bus system.

Thus, the receiving unit receives only DRM data signals of an adjustable frequency and provides the received data to the bus system. For this purpose, an evaluation of the received data is performed within the receiving unit to determine whether the data has been addressed for this receiving unit. If the addressing is correct, the data will be forwarded to the bus system.

Alternatively, the receiving unit may be configured to receive DRM signals with multiple adjustable frequencies in the LW or MW range.

According to a further embodiment of the invention, the transmission is encrypted. In this case, key information of a cryptographic method can be transmitted between the receiving units via the various adjustable frequencies. In addition, the receiving unit can be controlled by means of different transmission protocols.

Accordingly, the receiving unit is designed so that multiple frequencies can be received or evaluated simultaneously. This can advantageously be used, in particular, to transmit different keys of a cryptography method to receiving units via different data channels with different frequencies. Thus, the different key information can be used to perform mutual acknowledgments over different data channels. to create a trust network within a cryptography process. This requires no special knowledge of the specific transmission protocol of the radio transmission, since the receiving units make a corresponding coding with respect to the different frequencies and transmission protocols and in each case only the appropriate receiving unit can perform a decoding of the encrypted signals. A leveraging of security protocols or the like is thus prevented or extremely difficult, which would otherwise not be possible if the receiving unit were not connected to the Internet, for example, to form access interfaces.

Some embodiments will be explained in more detail with reference to the drawing. 1 shows a radio-controlled system according to the invention in a schematic illustration

2 shows a further embodiment of the radio-controlled system according to the invention in a schematic representation,

Fig. 3 shows a further embodiment of the radio-controlled system according to the invention in a schematic representation, and

4 shows a further embodiment of the radio-controlled system according to the invention in a schematic representation.

In the figures, identical or functionally identical components are provided with the same reference numerals. 1, a first embodiment of a radio-controlled system FS according to the invention is explained in greater detail below.

The radio-controlled system FS comprises a transmitting unit SE, which transmits radio waves RW, for example as an AM transmitter or FM transmitter, to a receiving unit EE via a transmitting antenna SA. The radio waves RW are received at the receiving unit EE via a receiving antenna EA, and supplied to an input processing unit EV. The input processing EV on the one hand provides the energy required for the receiving unit EE, which is taken from the radio waves RW. On the other hand, possibly existing modulated signal contents, such as control commands, address information or the like, are removed from the signal transmitted by the transmitting unit SE in the input processing EV and forwarded together with the power supply via a signal path SP. In this case, control messages can be contained in the signal transmitted via the radio waves RW, which are forwarded to a sensor unit SN. In general, instead of the sensor unit SN, it is also possible to use a processing unit which, for example, further processes data received in the form of a processor via the signal path SP. Likewise, the processing unit can also process directly as a demodulator the received radio waves RW. Likewise, it is provided within the scope of the invention that the sensor unit SN can be part of a processing unit.

The sensor unit SN in turn can, starting from these control messages, an electrical signal, for example via the signal path SP, to a Pass actuator that converts this electrical signal into a mechanical movement.

The possibilities of processing data within the receiving unit EE are very diverse. Thus, the sensor unit SN can be used as a GPS

Receiver can be formed, which receives correction signals via the transmitting unit SE as a control message, so that by means of a differential GPS method, an accurate location information with respect to the location of the receiving unit EE can be derived.

In still other applications, the control message can be used as an internal configuration signal for the sensor unit SN or include corresponding control commands. In still other applications, it is possible to execute a mechanical activity by means of the actuator AK via the control messages or the measured values determined by the sensor unit SN. This activity may include both moving the receiving unit EE as a whole, including the control of valves, switches or the like. By way of example, the use of the radio-controlled system FS according to the invention is explained using the example of an irrigation system. Here, the sensor unit SN can be designed so that it determines parameters such as temperature or humidity of the soil and provides via the actuator AK for a corresponding irrigation.

FIG. 2 shows a further embodiment of the radio-controlled sensor system FS according to the invention. Here, a plurality of receiving units EE1, EEN are provided, so that the transmitting unit SE via the transmitting antenna SA radio waves RW in the form of a 1: N transmission to multiple receivers performs. In this case, the different receiving units EE1, EEN can perform both identical and different tasks, which can be done for example by means of an individual addressing, wherein the above-described distinction by means of the exact location information is also possible.

In still other embodiments, it may be necessary to provide the further components, which are associated, for example, with the actuator or the sensor unit SN, with their own power supply, which, for example, can also be activated by means of the input processing EV. Thus, it is not necessary to power external components via the radio waves RW.

With reference to Fig. 3, a further embodiment of the receiving unit EE will be described below. The receiving unit EE in turn has a receiving antenna EA, which is designed in the example shown as an internal antenna. The antenna signal of the receiving antenna EA is passed on to a tuner TU, which is typically designed for the frequencies FM, DVB-T2, DAB, DAB +, MW and LW to receive and decode DRM transmissions. The received signals are forwarded both to a module for audio processing AV, a module for data processing DV and to a control processor ST as a processing unit. Such a procedure differs only slightly from that shown in FIG. 1, wherein in the example of the receiving unit EE shown in FIG. 3, the decoded signals can be forwarded to an interface SC via an interface module SB.

It is likewise possible to receive signals from the interface SC via the interface module SB, which signals are forwarded to the control processor ST. the. The control processor ST is in turn connected to the tuner TU, so that via the interface SC, for example, the transmission channel, the transmission frequency or the type of signal to be received can be selected. The control processor ST has for this purpose a specially developed control software, which is stored in a corresponding instruction memory (not shown in Fig. 3), so that communication with both the interface module SB and with the tuner TU is possible. The interface SC can be designed both wired and wireless, in the latter case offers a Blotoose connection. The interface SC is connected to a mobile terminal ME, which is designed in the form of a mobile phone or a tablet PC.

Accordingly, it is possible to generate via a corresponding application software AS on the mobile terminal ME corresponding control signals, which are continued via the interface SC to the control processor ST or to receive data from the module for audio processing AV or the module for data processing DV be continued via the interface module SB and the interface SC to the mobile terminal ME. Accordingly, the mobile terminal ME for a user provides a user interface for the receiving unit EE. The desired reception frequency and function are selected via the application software AS. By way of example, FM can be set as the reception frequency, so that the playback of radio signals is now possible on the mobile terminal ME. When setting the reception frequency LW, for example, GPS

Correction data can be displayed on the mobile terminal ME. If, for example, DVB-T2 is selected as the reception frequency, it would be possible to display digital TV channels on the mobile terminal. Accordingly, the function of the mobile terminal is extended by passing it over the interface point SC is connected to the receiving unit EE. In one embodiment, the receiving unit EE can have an internal power supply IS, which can also be used in addition to charging the mobile terminal ME. This function can also be controlled via the control software stored in the control processor ST. In the reverse direction, it is also possible to supply the receiving unit EE via the battery storage of the mobile terminal ME. In addition, an interface for an external antenna receiving system can be provided in addition to the internal receiving antenna EA.

With reference to FIG. 4, a further embodiment of the receiving unit EE according to the invention will be described below. In this embodiment, it is not necessary to equip the receiving unit EE with its own power supply.

The receiving unit EE is used for DRM transmission in LW and MW frequency ranges. The receiving unit EE receives to exclusively DRM data signals, d. H. no audio or video signals. For this purpose, for example, an external receiving antenna EA, which is connected to a customary transmission medium with the receiving unit EE, is provided, wherein alternatively or additionally, an internal receiving antenna EA 'can be used. The receiving antennas EA and EA 'are fed to a receiving module EM, which can receive corresponding LW and / or MW frequencies. In this case, only one adjustable frequency is received on the receiving unit EE in this embodiment.

The received signal is passed on to a demodulator module DM, which forwards the received data to a control module SM as a processing unit. Between the control module SM and the demodulator module DM Control signals can be exchanged. The control module SM is also equipped via a user interface Ul, which may be embodied for example in the form of a USB interface, an Internet interface or the like, for communication with external devices. These can be used, for example, to store or modify corresponding control commands within the control module SM.

The output of the control module SM can be forwarded to a utilization device NG1 or a utilization device NG2. For this purpose, the output of the control module SM is connected to an interface module IM, which processes the data received from the control module SM and forwards it to the utilization device NG2. Alternatively, it is provided to forward the non-processed data, which are taken directly from the bus system BS before the interface module IM, to the utilization device NG2.

It is now possible for a user to use the bus system BS directly and to process the data provided independently, for example, on the user device NG1. Alternatively or additionally, a user device NG2 can be connected via the already provided interface module IM.

The internal control module SM evaluates the received data signals and checks whether they have been addressed for this control module SM. If the addressing is correct, the data is forwarded to the bus system BS. These are exclusively digital data such. GPS correction data, text messages and control signals.

In addition to the functionality of the receiving unit EE explained in connection with FIG. 4, it is possible to provide several frequencies at the same time. tig to receive and evaluate. As an application, this receiving unit EE then serves as a node within a trust network in the context of a cryptography method. For this purpose, various encryption information is transmitted to the receiving unit EE via different data channels, which can cover different frequencies of the radio signal, which must be mutually confirmed with encryption information from other receiving units. The keys are transmitted by radio using different frequencies and are encrypted or coded there. The decoding can only be carried out with a suitable receiving unit EE.

In contrast to previous methods, this results in an increased security, since several different data channels can also be used with different frequencies. The radio transmission is possible in the LW and MW frequency range. In order to be able to transmit signals from the outside by radio, greater expenditures are necessary because, for example, antennas with several 100 m in height or transmitters with several kW of transmission power would have to be provided. Furthermore, it is also provided to use different protocols at different frequencies, in which case no knowledge about special transmission protocols must be available to the user due to the decoding carried out independently via the receiving units EE. Accordingly, it is possible to create a trust network of distributed devices, wherein an access interface exists even if the receiving unit EE, for example, would not be connected to the Internet as usual. Accordingly, there is no possibility of gaining unauthorized access and the raising of security protocols is impossible or so difficult that reasonably no access of unauthorized participants is to be expected. The features indicated above and in the claims, as well as the features which can be seen in the figures, can be implemented advantageously both individually and in various combinations. The invention is not limited to the exemplary embodiments described, but can be modified in many ways within the scope of expert knowledge.

Claims

Claims:

Radio-controlled system for data transmission, which has a transmitting unit which transmits electromagnetic radio waves to a receiving unit by means of terrestrial transmission, wherein the receiving unit can be activated upon arrival of the electromagnetic radio waves, wherein the transmitting unit sends a control message or information to the receiving unit via the radio waves, so that a arranged on the receiving unit processing unit undergoes a state change, wherein after the end of the transmission of the electromagnetic radio waves, the receiving unit is deactivated.

Radio-controlled system according to claim 1, wherein the processing unit arranged on the receiving unit comprises a sensor unit, a demodulator or a calculation unit.

Radio-controlled system according to claim 1 or 2, in which the sensor unit arranged on the receiving unit receives correction signals from the transmitting unit as a control message in order to generate location information by means of a differential GPS method.

A radio controlled system according to any one of claims 1 to 3, wherein the control message is routed to an actuator which effects a mechanical movement which is implemented by either the receiving unit as a whole or other components located thereon.

5. A radio-controlled system according to any one of claims 1 to 4, wherein the processing unit uses the control message as control data. 6. Radio-controlled system according to one of claims 1 to 5, wherein the transmitting unit and the receiving unit for the frequencies FM, DVB-T2, DAB, DAB +, MW and / or LW and / or are designed for DRM transmissions.

7. Radio-controlled system according to one of claims 1 to 6, wherein a plurality of receiving units is provided, which are controllable by a transmitting unit.

8. Radio-controlled system according to one of claims 1 to 7, wherein the sensor unit on the receiving unit determines pressure, temperature, humidity or other environmental parameters.

9. Radio-controlled system according to claim 4 and 8, wherein the actuator is part of an irrigation system.

10. Radio-controlled system according to one of claims 1 to 7, wherein the receiving unit is part of a means of transport for goods and / or passenger transport or part of a power supply unit.

1 1. Radio-controlled system according to one of Claims 1 to 10, in which the transmitting unit transmits ambient and / or status information as a control message which links the receiving unit to local control parameters.

12. Radio-controlled system according to one of claims 1 to 1 1, wherein the power supply of the receiving unit via the electromagnetic radio waves takes place. 13. Radio-controlled system according to one of claims 1 to 12, wherein the receiving unit has an interface to a mobile terminal. 14. A radio-controlled system according to claim 13, wherein the receiving unit is configured with an internal power supply, that a loading of the mobile terminal is possible, or in which the receiving unit can be supplied via a power supply of the mobile terminal. 15. A radio-controlled system according to claim 13 or 14, wherein the receiving unit is controllable via the mobile terminal.

16. Radio-controlled system according to one of claims 13 to 15, wherein the received signals from the receiving unit to the mobile terminal device are forwarded.

17. Radio-controlled system according to one of claims 13 to 16, wherein the receiving unit is part of the mobile terminal. 18. Radio-controlled system according to one of claims 1 to 12, wherein the receiving unit has a connection for a bus system.

19. A radio-controlled system according to claim 18, wherein an interface module is arranged between the receiving unit and the terminal, the signals supplied to the interface module being relayed to a further terminal. 20. The radio-controlled system according to claim 18 or 19, wherein the receiving unit is adapted for the reception of DRM signals with a single adjustable frequency in the LW or MW range.

21. A radio-controlled system according to claim 20, wherein the receiving unit is addressable via the received DRM signal and, in accordance with a predetermined value, forwards the possibly decoded received signal to the terminal for a bus system.

22. A radio-controlled system according to claim 18 or 19, wherein the receiving unit is adapted for the reception of DRM signals with a plurality of adjustable frequencies in the LW or MW range.

23. A radio-controlled system according to claim 21, wherein the transmission is encrypted.

24. Radio-controlled system according to claim 22, wherein key information of a cryptographic method is transmitted between the receiving units via the various adjustable frequencies.

25. Radio-controlled system according to claim 24, wherein the receiving unit can be controlled by means of different transmission protocols.