WO2008031632A1 - High-frequency transmitter and associated operating method - Google Patents

Abstract

The invention relates to a high-frequency transmitter and an associated operating method. Said high-frequency transmitter (1) contains: an energy transducer (2) for supplying energy to the high-frequency transmitter; a logic component (3) that is connected to a receiver circuit for the executive sequencing of the high-frequency transmitter; and a high-frequency transmission stage for radio communication. According to the invention, at least some regions of the energy transducer (2) are designed as an input element for non-electric control signals, in order to generate electric input signals for the receiver circuit.

Description

Radio frequency transmitter and method for its operation

The present invention relates to high-frequency transmitters, which are preferably designed as wireless energy self-sufficient systems and have digital circuits for data processing and flow control.

These regularly contain an energy converter for supplying power to a high-frequency transmitter, a logic module connected to a receiver circuit for sequencing the radio-frequency transmitter, and a radio-frequency transmission stage for radio communication. The energy generated by the energy converter is buffered or stored in an electrochemical energy store. For small sizes, these energy self-sufficient systems have the problem that the power consumption is very limited. For many years of use or especially small sizes, the performance of conventional energy storage devices is often insufficient. right.

Based on this prior art, the present invention has the object to provide a high-frequency transmitter, which can be operated as a self-sufficient energy system even in long-term operation and still operates with a relatively small size with relatively high transmission power.

This object is achieved by a high frequency transmitter according to the independent claims.

The high-frequency transmitter according to the invention contains an energy converter for supplying energy to the high-frequency transmitter, a logic module connected to a receiver circuit for sequential control of the high-frequency transmitter, and a high-frequency transmission stage for radio communication. The energy converter is at least partially formed for non-electrical control signals or signals as input element for generating electrical input signals for the receiver circuit. In this case, it is particularly advantageous that non-electrical signals or input signals can be used (that is, for example, light, mechanical vibration / vibration, sound, temperature changes, etc.). These effects are then used in the corresponding energy converter of the energy supply, also the non-electrical signals are also used as a source of information. For this purpose, a further processing to an electrical

Signal, which can then be used as an input signal for the secondary receiver circuit. This means a clear demarcation of transponder applications, which, although relatively small in size, can be constructed, in which, however, control signals or input signals always in electrical form and not in non-electrical form (light, sound, vibrations, temperature changes). The sequence control of the high-frequency transmitter can be activated via these input signals or signal sequences or system parameters can be set accordingly.

Due to the additional use of the energy converter as a receiver, extremely low-power sensor systems of very small size or long service life can be realized. This opens up a variety of applications such as recording of environmental conditions, monitoring of moving objects, warning of material fatigue in rotating parts, inventory management and control, structural analysis of infrastructure. The ability of the free configurability of wireless sensor systems to be easily adaptable for new applications promises great market potential.

The activation or adjustment of system parameters supported by the energy converter can reduce the power consumption. In addition, the transmitted signals can also serve for wireless charging, so that the extended configuration functionality does not have to be included in the energy budget (ie, the signal sequences of the input signal used for the control can even be used for energy in the energy converter). This enables extremely low-power systems with a particularly long service life or with a smaller energy storage unit or a smaller energy converter. In the case of a smaller power supply or by the possibility of getting along with fewer components, a lower weight or a higher mechanical robustness is achieved. This allows safe operation in harsh environments with high accelerations. For application-specific implementation of the energy converter with integrated receiver functionality, several different precautions are preferably to be taken. This concerns first of all the tuning of the energy converter to the signal to be received. Since the receiver circuit evaluates a specific sequence of current or voltage levels, the signal to be received with the energy converter in the sense of a high selectivity compared to the typical environmental parameters is preferably suitably adapted. In the case of solar cells, this may mean covering a small area with optical films or with an optical coating in order to allow only a certain spectrum as a signal for activation or configuration. For Pietzowandlers, for example, a specific cutout can increase the sensitivity of certain harmonics, which then trigger activation or configuration.

Furthermore, it makes sense to realize a very low-power evaluation circuit. The energy converter converts the signals to be received as current or voltage amplitudes. Depending on the application, simple modulation schemes and decoding methods are used to implement the evaluation circuit, so that, for example, threshold value detectors in conjunction with delay elements achieve a particularly high-performance decoding of specific instruction sequences.

Another aspect of the invention is a method for operating the high-frequency transmitter according to the invention, wherein the sequence control of the high-frequency transmitter by special pulse sequences in the form of light pulses, vibrations and / or temperature changes can be influenced.

In the following, advantageous developments of the invention will be described.

An advantageous embodiment provides that the radio power of the high-frequency transmitter is between 1 and 100 milliwatts, preferably between 1 and 10 milliwatts. Here, the total volume of the high-frequency transmitter is preferably less than 1 cubic centimeter, more preferably less than 100 cubic millimeters, and most preferably less than 64 cubic millimeters.

The comparatively high transmission power in such a small volume is achieved primarily by the synergy of the energy converter, which is also designed as an input element for generating input signals for the receiver circuit and is also designed to generate energy. Of the

Radio frequency transmitter is preferably operated in interval mode, i. that periodically or on request, the high-frequency transmission stage comes into action. In this case, the high-frequency transmission stage can determine specific measured values of a sensor for detecting

Environmental conditions, in particular a temperature sensor and / or a vibration sensor shipped. In this case, data determined by the sensors can also be intermediately stored in a data memory, wherein the data memory is connected to the logic module of the

Radio frequency transmitter is connected.

To further save energy, the receiver circuit may be provided with a so-called "wake-up circuit ^11. This makes it possible that strong radio signals are sent on request and In other stand-by mode, the radio-frequency transmitter can be operated with a very low power consumption, which is, for example, more than covered by the energy converter during operation. The evaluation circuit can be realized for example in a simple manner with a threshold detection in conjunction with delay elements.

The high-frequency transmitter can be designed in different ways or with different complexity. Required is at least one radio frequency transmission stage for radio communication. In a further embodiment, however, it is also possible to provide a high-frequency receiver stage. This is useful, for example, if larger control sequences are to be sent to the high-frequency transmitter (of course only after activation by a specific pulse sequence, which was sent to the energy converter). Such a high-frequency receiver stage can also be useful for "forwarding" certain signals in a network.

The radio-frequency transmitter usually has a radio-transmission circuit which is provided with a micro-antenna for transmitting and receiving radio signals.

In addition, the high-frequency transmitter will usually have a preferably electrochemical energy store, wherein the energy store is at least indirectly connected to the energy converter. The energy converter preferably contains photoelectric elements for evaluating light pulses by the receiver circuit. These photoelectric elements can be formed, for example, as a solar cell, which is preferably partially covered with an optoelectronic element. see coating and / or foil is occupied (such a coating or foil serves primarily to improve the selectivity by filtering certain wavelengths). Another advantage of using solar cells is that they can be mounted on the outside of the high-frequency transmitter (the high-frequency transmitter is preferably approximately cube-shaped) and here also serve for the vertical contacting of the individual modules.

Different embodiments are useful for the solar cells.

Preferably, the material of the solar cells (such as amorphous silicon gallium arsenide, cadmium telluride) is deposited in the vapor phase on carrier material. A layer thickness of 1 to 10 micrometers makes sense here.

Thus, in a first variant, it is possible to process the solar cell directly onto a component. Here, a device area is used of semiconductor material (from a microchip or ceramic substrate, such as a sensor or quartz) on which the solar cells are directly deposited.

Another variant provides that the solar cell is applied as a flexible film. For this purpose, solar cells are applied to film material such as polyimide (PI), benzocyclobutene (BCB) with a thickness of, for example, 50 micrometers and further processed as a flexible component.

In a further variant, the solar cell is provided as a flexible film with "printed circuit board functionality". This film substrate can also Ladder cables for vertical contacting of individual modules of the example cube-shaped high-frequency transmitter contained.

In an alternative or additional energy converter, a piezoelectric element for evaluating vibration sequences can be provided by the receiver circuit. In this case, the piezoelectric element can, for example, also have cutouts for detecting specific harmonics of the piezoelectric element in order to increase the selectivity of the signal sequences which, for example, are to activate a specific sequence of the high-frequency transmitter.

A further advantageous embodiment provides that the energy converter identifies at least one electromagnetic element for evaluating electromagnetic pulses.

Finally, a further embodiment provides that the energy converter has a thermoelectric element for the evaluation of temperature changes by the receiver circuit. Here is generated by the thermoelectric element on the one hand, an activation of these otherwise inert components but for example by means of applied "freeze spray" (for example, starting from liquid nitrogen) readily possible.

It is important that the receiver circuit of the high-frequency transmitter can be designed such that system functions can be triggered and / or synchronized by the logic module due to specific input signals or that the receiver circuit of the high-frequency transmitter is configured in such a way that that the input signals can cause a change of system parameters.

As a result, the high-frequency transmitter or a plurality of high-frequency transmitters can be programmed by certain pulse sequences, which are recorded by the energy converter, wirelessly.

The present invention does not relate to RFID technology, the typical feature of which is to use electromagnetic waves (electrical signals) from a base station as an energy source as well as for communication. The energy converter referred to here converts non-electrical energy (in the form of sound, vibrations, temperature changes or light) into electrical energy or non-electrical environment signals for the receiver circuit into electrical signals. Favorable here is the energy self-sufficient and small concept, so that sizes of less than 1 cm ^{3 are} easy to produce. The "wake-up circuit" according to the invention is hardly relevant for use in transponders, but important for the functionality of radio sensor nodes in the context of the present invention.

Interesting developments of the present invention can be summarized as follows.

The invention relates to energy converters for

Energy supply from high-frequency transmitters, whereby the energy converters can not convert electrical energy from the environment into electrical energy (however, an additional rather energy converter, for example, an electromagnetic table energy or electrical energy immediately provides).

However, it is important that certain non-electrical signal sequences can control the functionality of the high-frequency transmitter. For this purpose, the energy converter may, for example, have photoelectric elements in order to convert light energy into electrical energy and at the same time in conjunction with the receiver circuit and the logic module to be able to evaluate light pulses for controlling the radio transmitter. It is also advantageous that the energy converter has piezoelectric, electrostatic or electromagnetic elements in order to convert vibrations into electrical energy and, at the same time, in conjunction with the receiver circuit and logic module, to be able to evaluate vibrations in specific sequences and frequencies for controlling the radio transmitter.

It is also interesting that the energy converter has thermoelectric elements in order to convert heat differences into electrical energy and at the same time, in conjunction with the receiver circuit and the logic module, to be able to evaluate temperature changes in a certain range and duration for controlling the radio transmitter.

A refinement provides that the radio-frequency transmitter has a data memory which is connected to the logic module and / or contains one or more sensors for detecting environmental conditions whose measurement results can be transmitted by the radio-frequency transmitter and / or which has a radio-frequency receiver stage which is temporary can process larger amounts of data and allows operation in wireless networks. It is also important for the method according to the invention that the non-electrical signals in the form of light pulses, vibrations, sound and / or temperature changes from an external device

Functionality of the radio frequency transmitter can be controlled specifically. With this targeted control is of course not meant that is disturbed by very strong vibrations of the functional sequence of the high-frequency transmitter so that this is considered changed, but it is hereby a targeted control (for example, an increased transmission or switching to a sleep mode) sought , In this case, the non-electrical signals from the external device can be used to switch the radio-frequency transmitter from a power-saving mode into a specific operating mode, to trigger a synchronization of the radio-frequency transmitter or to allow a configuration of the operating modes of the radio-frequency transmitter.

Further advantageous developments are described in the remaining dependent claims.

The invention will now be explained with reference to several figures. Show it:

Figure 1: The general structure of the energy self-sufficient system with energy converter and integrated activation or configuration functionality

Figure 2: The structure of a high-frequency transmitter according to the invention in cube shape with an edge length of 4 millimeters FIG. 1 shows the general structure of the energy self-sufficient system with energy converter and integrated activation or configuration functionality. The energy converter shown on the left side, which can be embodied, for example, as a solar cell, converts ambient energy in the form of light into electrical energy both in a photovoltaic manner. At the same time, corresponding activation or configuration signals in the form of a specific sequence of light flashes can be picked up by the energy converter and of course also contribute to the energy balance. These corresponding input signals, which are converted into electrical pulses by the photovoltaic conversion of the light pulses, forms an input signal which undergoes signal filtering or signal conditioning in the receiver circuit (lower middle box in FIG. 1). The upper middle box in FIG. 1 shows that the electrical energy coming from the energy converter likewise undergoes energy conditioning or load adaptation (for example in a buffer capacitor) as well as subsequent energy storage (for example in a dedicated electrochemical energy store). Thus, the input signal and also the supplied electrical energy in the system functionality / the energy management are summarized, as the right-hand box in Figure 1 shows.

FIG. 2 shows an example of a high-frequency transmitter according to the invention. The high-frequency transmitter 1 has an energy converter 2, which shows photoelectric elements for the evaluation of light pulses by the receiver circuit. The photoelectric element is in this case formed as a solar cell (or as a 6 × 3 array of solar cells). One of these single cells is preferably with an optical coating and / or a film, the filtering of the light achieved thereby increases the selectivity between the input signal to be detected (an intended sequence of light pulses) and the usual light which extends over the entire surface of the solar cells

Generation of electrical energy allows. The energy converter 2 is connected on the one hand to the energy store 7 and also to a logic subassembly 3. The logic board 3 is connected to a receiver circuit. This receiver circuit evaluates the input from the energy converter 2 input signal. The receiver circuit in this case has a "wake-up circuit". This ensures that in "idle mode"("stand-bymode") a minimum energy consumption of the high-frequency transmitter is given or that it runs fully self-sufficient energy. After activation, for example, by a predetermined sequence of light pulses, the receiver circuit is "woken up" and the radio frequency transmitter is fully operational. In this case, the receiver circuit of the high-frequency transmitter can be configured such that, due to specific input signals, system function can be triggered and / or synchronized by the logic module or the input signals can cause a change of system parameters of the high-frequency transmitter. The logic module 3 is in turn connected to a temperature sensor 8, which measures the ambient temperature. The read signals of the temperature sensor are stored on demand via a data memory 4 also connected to the logic module. Depending on the input signal, then, for example, measured temperature values of the temperature sensor 8 can be transmitted via a radio transmission circuit 5, which belongs to the logic module 3 and transmitted via a microantenna 6, a corresponding quartz 9 is on the surface of the essential cube-shaped high-frequency transmitter to the left of the buffer capacitor 10, which is in communication with the energy storage given.

The illustrated high-frequency transmitter 1, which can take other forms, for example, in the present case has a total volume of about 64 cubic millimeters, the radio power of the high-frequency transmitter is about 5 milliwatts.

The high-frequency transmitter shown in FIG. 2 thus contains a high-frequency transmitter 1: an energy converter 2 for supplying energy to the high-frequency transmitter, a logic module 3 connected to a receiver circuit for sequencing the high-frequency transmitter, and a high-frequency transmission stage for radio communication, wherein the energy converter 2 is at least partially formed as an input element for generating input signals for the receiver circuit.

This high-frequency transmitter can be operated so that the sequence control of the high-frequency transmitter can be influenced by special pulse sequences in the form of light pulses.

A main application of the high-frequency transmitter shown in FIG. 2 is, for example, the temperature measurement or the measurement of a temperature field with a plurality of such high-frequency transmitters. For this purpose, corresponding high-frequency transmitters are mounted, for example, on an engine test bench on an engine block. The change in the temperature field over time should be determined. This is done by targeting the temperature at different times. The activation of the radio frequency transmitter for the desired measured values are obtained by generating a predetermined sequence of light flashes within the space in which the test stand is constructed. This results in a simultaneous reading of the corresponding signals from the temperature sensor 8 or the data memory 4, which are then forwarded via a radio transmission circuit 5 and the micro-antenna 6 to a receiving station.

An advantage of this is that the previously necessary

Cabling, which may also be susceptible to heat or build up a disturbing electric field, have become dispensable. The transmission of the measuring signals is carried out by the micro-antenna 6, the energy requirement is covered by the energy converter 2 (solar cells), so that no cables are necessary.

Another area in which high-frequency transmitters according to the invention are applicable is, for example, the tire pressure measurement. Here, in principle, the same components are used as described above, but instead of an energy converter 2 in the form of solar cells preferably a piezoelectric element, which gains energy through vibration applied. Instead of or in addition to a temperature sensor 8, an air pressure measuring sensor is provided. This ensures that, on the one hand, there is continuous charging of the energy store 7 due to the inevitably occurring vibrations during rotation of the tire in a motor vehicle. In certain situations, for example when starting the vehicle, a special vibration sequence is additionally exerted on the piezoelectric element by a control unit of the motor vehicle, so that it is activated to output the measured value and the Values of the air pressure sensor via the micro-antenna 6 is sent to the control unit of the motor vehicle for checking sufficient air pressure. An improvement in the selectivity of the targeted vibration sequence for activation and "normal" vibrations within the tire operation can be achieved in that the piezoelectric element has special recesses so that it develops additional resonances at certain overshoots. Now, if a corresponding frequency is generated by the control unit of the motor vehicle, a high selectivity can be displayed.

For the high-frequency transmitter according to the invention still further possibilities come into consideration. In addition to energy converters in the form of electromagnetic elements in particular energy converters in the form of thermoelectric elements come into question, which react to temperature changes. However, these quite inert systems can still be safely activated by targeted temperature jumps, for example by applying "cold spray".

Finally, it should be noted that in addition to the transmission own shanks of the high-frequency transmitter this may also contain a high-frequency receiver stage, which also receive additional radio signals after activation of the high-frequency transmitter by a corresponding input signal of the energy converter (in the context of this application is always preferred with radio meant high-frequency electromagnetic radiation).

The embodiments described above are to be understood purely by way of example, all combinatorial Onsmöglichkeiten the appended claims should be encompassed by the present invention.

Claims

claims

A high-frequency transmitter (1), comprising: an energy converter (2) for supplying power to the high-frequency transmitter, - one connected to a receiver circuit

Logic assembly (3) for sequencing the radio frequency transmitter and a radio frequency transmission stage for radio communication, characterized in that the energy converter

(2) is formed at least in regions for non-electrical control signals as an input element for generating electrical input signals for the receiver circuit.

2. Transmitter according to claim 1, characterized in that the radio power of the high-frequency transmitter (1) is between 1 and 100 mW, preferably between 1 and 10 mW.

3. Transmitter according to one of the preceding claims, characterized in that the total volume of the high-frequency transmitter (1) is less than 1 cm ³ , preferably less than 100 mm ³ , more preferably less than 64 mm ³ .

4. Transmitter according to one of the preceding claims, characterized in that the high-frequency transmitter (1) has a data memory (4) which is connected to the logic module.

5. Transmitter according to one of the preceding claims, characterized in that the receiver circuit comprises a wake-up circuit.

6. Transmitter according to one of the preceding claims, characterized in that the high-frequency transmitter (1) has a radio transmission circuit (5).

7. Transmitter according to claim 6, characterized in that the high-frequency transmitter (1) has a micro-antenna (6) connected to the radio-transmitting circuit (5) for transmitting and / or receiving radio signals.

8. Transmitter according to one of the preceding claims, characterized in that the high-frequency transmitter (1) has a preferably electrochemical

Energy storage (7) for energy storage, wherein the energy storage is connected to the energy converter (2).

9. Transmitter according to one of the preceding claims, characterized in that the energy converter

(2) has photoelectric elements for evaluating light pulses by the receiver circuit.

10. Transmitter according to claim 9, characterized in that the photoelectric element is formed as a solar cell, which is preferably partially covered with an optical coating and / or film.

11. Transmitter according to one of the preceding claims, characterized in that the energy converter

(2) a piezoelectric element for evaluation of vibration sequences by the receiver circuit.

12. Transmitter according to Claim 11, characterized in that the piezoelectric element has cut-outs for detecting specific harmonics of the piezoelectric element.

13. Transmitter according to one of the preceding claims, characterized in that the energy converter (2) has at least one electromagnetic element for evaluating electromagnetic pulses.

14. Transmitter according to one of the preceding claims, characterized in that the energy converter (2) has a thermoelectric element for the evaluation of temperature changes by the receiver circuit.

15. Transmitter according to one of the preceding claims, characterized in that the receiver circuit of the high-frequency transmitter (1) is designed such that due to specific input signals system functions can be triggered and / or synchronized by the logic module.

16. Transmitter according to one of the preceding claims, characterized in that the receiver circuit of the high-frequency transmitter (1) is designed such that the input signals can cause a change of system parameters.

17. Transmitter according to one of the preceding claims, characterized in that the high-frequency transmitter (1) has a sensor for detecting environmental contains conditions, in particular a temperature sensor (8) and / or a vibration sensor, the measurement results of the high-frequency transmitter can be shipped.

18. Transmitter according to one of the preceding claims, characterized in that the high-frequency transmitter (1) contains a high-frequency receiver stage.

19. A method for operating a high-frequency transmitter according to one of the preceding claims, characterized in that the sequence control of the high-frequency transmitter can be influenced by special pulse sequences in the form of light pulses, vibrations, sound and / or temperature changes.

20. The method according to claim 19, characterized in that non-electrical signals are generated by an external device, which can switch the high-frequency transmitter (1) from a power-saving mode in a specific operating mode / transmission mode.

21. The method according to claim 19, characterized in that non-electrical signals are generated by an external device, which trigger a synchronization of the high-frequency transmitter (1).

22. The method according to claim 19, characterized in that non-electrical signals are generated by an external device, which allow a configuration of the operating modes of the high-frequency transmitter (1).