WO2007054384A1 - Apparatus and method for activating an electrical load - Google Patents

Abstract

The invention relates, in general, to an apparatus and a method for activating an electrical load and, in particular, to an apparatus and a method for uniquely identifying and activating a load from a group of a plurality of loads. The inventive apparatus for activating an electrical load contains receiving means for receiving a temporal sequence of frequency patterns, wherein each frequency pattern has a particular combination of signals at particular frequencies and with a sudden phase change, and detection means for detecting whether the particular combination of signals at particular frequencies which is contained in a frequency pattern is assigned to the electrical load. The apparatus also contains detection means for detecting whether each signal from the particular combination of signals has a sudden phase change and detection means for detecting whether the temporal sequence of the frequency patterns is assigned to the electrical load and means for activating the electrical load for the case of detection. The apparatus and the method are particularly highly suitable for activating a load from a group of loads if the loads are in the transmission range of a broadband interference transmitter.

Description

description

Device and method for activating an electrical consumer

The invention relates to an apparatus and method for activating an electrical consumer in general and to an apparatus and method for uniquely identifying and activating a consumer from a group of several consumers in particular.

State of the art

The lifetime and the service intervals of electrical loads which are of autonomous power sources, such as egg ner battery or a rechargeable battery, powered, depend primarily on the ratio between the energy consumption of the load and the energy storage capacity of Ener ^¬ source, which makes starting.

The service life or the maintenance intervals of electrical consumers that are found mostly in a wait state be ^¬ and are used only from time to time can be increased by allowing almost resting energized consumers and activated for use.

Consumers who are only used from time to time are eg radio sensors or automatic radio logbooks. For example, in each tire of a motor vehicle a radio sensor can be integrated, which serves to measure the air pressure in the tire. A is exploiting Dende in the vehicle transmit / receive unit builds in regelmä ^¬ lar intervals on a data connection with the wireless sensor, to obtain from the sensor measured data and weiterzuverar- BEITEN. In known systems, a clock is often used to activate the wireless sensor and establish data communication with the transceiver. However, even then power is consumed if no data transmission is to take place. Also problematic is the synchronization of the clock of the radio sensor with the clock of the transmitting / receiving unit, especially if the time between two activation ^¬ transactions is very long. Moreover, a communication with the wireless sensor is possible only at certain times, which prohibits an application in time-critical tasks.

Other systems use electromagnetic signals to activate consumers. However, often the electrical signal also serves to supply energy at the same time as with RFID tags.

The invention is therefore based on the object of specifying a verbes ^¬ serte device and a method for activating an electrical load.

The object is achieved with the device specified in claim 1 for the activation of an electrical consumer and with the specified in claim 8 method for activating an electrical load. Further advantageous embodiments are specified in the subclaims.

The invention provides an apparatus for activating an electrical load with receiving means for receiving a time sequence of frequency patterns, wherein each frequency pattern has a specific combination of signals with specific frequencies and a phase jump, with detection means for detecting whether they are in a frequency pattern contained certain combination of signals with certain frequencies assigned to the electrical is orders. The apparatus further comprises detection means for detecting whether each signal from the particular combination of signals has a phase jump, and detection means for detecting whether the time sequence of the frequency patterns is associated with the electrical load on.

Furthermore, there are means for activating the electrical load in the case of detection.

The apparatus for activating an electrical load comprises means for generating a second signal and a third signal from each signal from the combination Nati ^¬ on signals that are included in a frequency pattern associated with the consumer, and means for generating a fourth signal from the second signal by time delay of the second signal by a certain period of time. In addition, the device comprises means for superposing the third signal and the fourth signal and the further means for generating a fifth signal by superposing the third signal and the fourth signal, wherein the fifth signal is used to activate the one electrical consumer.

The device according to the invention can be used particularly advantageously for the selective activation of an electrical

Consumers who have an autonomous energy supply, from a group of consumers, since the other unreachable consumers are not activated.

In a preferred embodiment of the invention, the device for activating an electrical consumer comprises a frequency filter for detecting the frequency of each signal from the combination of signals having a frequency pattern associated with the consumer, a signal divider for generating the second signal and the third signal from each signal, further comprising a phase shifter and a time delay element for generating the fourth signal from the second signal and a signal mixer for superposition of the third signal and the fourth signal and for generating a fifth signal , An advantage of this embodiment is that the filters can be constructed of ceramic or piezoelectric components that do not consume energy when the load is at rest.

In another preferred embodiment of the invention, the device for activating an electrical load has a first surface acoustic wave filter (SAW filter), which is used to detect the frequency of each signal and to generate the third signal. Dar ^¬ over, the apparatus includes a second SAW filter to detect the frequency of the signal and for generating a third signal from the signal, wherein the second SAW filter is connected in parallel to the first. Furthermore, the device includes means for generating a fourth signal by time delaying the second signal using the first SAW filter. In addition, the device includes two transistors for superimposing the third and fourth signal, wherein the transistors are connected to the ers ^¬ th and second SAW filter, so that the fifth signal is the sum of the third signal and the fourth signal.

An advantage of this embodiment is that the parallel switched SAW filters are also used to detect whether the signal has a phase shift. As a result, by means of this embodiment, a device according to the invention can be provided which saves space and is therefore suitable for installation in particularly small sensors. In another embodiment, the device is characterized in that as a consumer radio devices are pre ^¬ see.

In another embodiment, the device is characterized in that the receiving means, the detection means and the means for activating the consumer are integrated in an electronic component.

This has the advantage that one can create a compact, small Ausfüh ^¬ tion form, which is suitable for installation in small consumers.

In another embodiment, the means for activating the consumer are used to put the consumer in a state of rest. The Vorrich according to the invention is particularly advantageous ^¬ tung be used if it is used for activating and deactivating the load. This has the advantage that the consumer consumes energy only when it is used. This leads to ei ^¬ ner extended life of the consumer or to larger maintenance intervals.

In another aspect, the invention relates to a method for activating an electrical load.

In a further aspect, the invention relates to a computer program product having computer-executable instructions for performing a method according to the invention.

Preferred embodiments of the invention will be explained in more detail with reference to the drawings. 1 shows a block diagram for activating an electrical load.

2 shows schematically a time sequence of

Frequency patterns. 3 shows schematically a connected to an antenna attached ^¬ filter bank.

4 shows an embodiment of a device for detecting whether a signal having a specific frequency has a phase jump. 5 shows a surface acoustic wave filter circuit.

6 shows a circuit diagram for a frequency ^{evaluation ¬} module.

7 shows a circuit diagram for the interconnection of

Frequency modules for evaluating the time sequence of the detected frequency pattern.

1 shows a block diagram of a device for activating an electrical load 102. The consumer holds environmentally while a receiving means 104 for receiving signals, the detection means 106, 124 and 128 and further comprising means for Akti ^¬ vation 108th

The receiving means 104 receives signals in the form of a zeitli ^¬ chen sequence 122 of frequency patterns, which are emitted by a transmitter 120th A frequency pattern 110 contains a combination of signals 112 with specific frequencies 116. The detection means 106 detects whether the frequencies 116 contained in the frequency pattern 110 are assigned to the load 102.

Furthermore advantage by means of the detection means 124 Detek ^¬ whether each signal 114 le in the combination of Signa ^¬ contained 112 has a phase jump 118th With the detection means 126 it is determined whether the temporal Sequence 122 of the frequency pattern is assigned to the consumer.

That the combination of signals 112 consists of one or more signals each having a particular frequency, each signal having a phase shift. A possible transmitter, for example, is a functional device capable of sequentially simultaneously transmitting or receiving signals at different frequencies in accordance with a standardized wireless solution according to IEEE 802.11.

It is detected that contained ^¬ in a frequency pattern 110 requested frequencies 118 are assigned to the consumers and that the time sequence 122, the frequency pattern 118 is also the consumer is assigned to 102 and further each Sig nal 114 has ^¬ a phase shift, then the consumer is using the activation means 108 is activated.

As a result, a consumer from a group of consumers can be identified by means of a sequence of frequency patterns. The phase jump which each signal must contain, for example, prevents a broadband jammer transmitting signals on all frequencies assigned to the consumer 102 from activating the consumer because it is unlikely that the emitted by the jammer signals at all frequencies, which has a signal combination, at the same time have a phase jump. The device and the method are therefore particularly well suited for the selective activation of a consumer 102 among several consumers even when the consumers are in the transmission range of a "jamming transmitter".

Particularly advantageous is the device and the method according to the invention for use in maintenance-free Sensors for monitoring automotive components, such as tires or for monitoring systems and machines.

FIG. 2 shows by way of example a temporal sequence of frequency patterns 212, 214, 216 and 218 which are used to activate a

Consumer 102 is used. Here, the frequency ^¬ pattern 212 includes the signals 202, 204 and 206 with the frequencies fl, f3 and f5. Frequency pattern 214 includes signals 208 and 210 having frequencies f2 and f4, respectively. Frequency pattern 216 includes signals 230, 232 and 234 having frequencies fl, f2 and f5, respectively, and frequency pattern 218 includes a signal 236 having frequency f4. The graph 222 shows, by way of example, the profile of the electric field component 224 over the time 226 of the signals contained in the frequency patterns. Each signal contains a phase jump 228 in the course of time of the electric field component (and thus correspondingly in the temporal course of the magnetic field component).

3 schematically shows a filter bank connected to an antenna 302. The antenna 302 is a possible exporting ^¬ approximate shape of the receiving unit. The filter bank is a possible embodiment of a part of the detection means. The filter bank contains a number of n individual filters for n different frequencies fl, f2, ... fn. In FIG. 300, four filters are shown for the sake of simplicity, with filter 304 filtering out a signal of frequency fl from the frequency pattern. Filter 306 filters a signal at frequency f2, filter 308 filters a signal at frequency f3, and filter 310 filters out a signal at frequency fn. Filtering here means that, for example, only the signal of the frequency fl reaches the output 312. Signals with different frequencies are blocked by filter 304. The same applies to the other frequency filters 306, 308 and 310. The consumer is thus assigned certain frequencies by the frequency filter located on the filter bank.

The filter bank is realized by means of known ceramic or piezoelectric resonators with high quality, which do not burden the power supply of the connected consumer, but alternatively also other forms of execution of the frequency selection are suitable.

, The 300 quenzmuster means of filter bank according to from the received Fre ^¬ selected few signals fl, f2, f3 fn, ... via the outputs 312, 314, 316, 318 each having a circuit as shown in Figure 4, respectively.

4 shows an embodiment for detecting whether a signal having a specific frequency has a phase jump. This is following the output of each frequency filter of a filterbank as shown in FIG. A signal S1 402 having a frequency f is divided by a signal divider 404 into two signals S2 416 and S3 412, the frequency of S2 416 and S3 412 corresponding to the frequency of S1 402. S2 416 is transferred by a 180 ° phase shifter and time delay element 406 with a preset time delay τ into a signal S4 410 which is superimposed by the signal mixer 408 with S3 412.

The graph 420 represents the time course of the electric field component of the signal S3 412 represents the signal mixer 408. Accordingly, the graph 422 the time course of the electric field component of the signal S4 410 on Signalmi ^¬ shear 408 represents the 180 ° -.. Phase shifter and the Zeitverzöge ^¬ approximately membered 406 is now designed so that S3 412 416 S2 with respect to a non-negative integer multiple of the time duration 1 / (2f) is delayed. So Thus, τ = n / (2f), where n ^¬ at a non-negative integer, and where f is the frequency of the signal is Fre ^¬.

The signal mixer 408 is now added S3 412 and S4 410. The time course of the electric field component of the resul ^¬ animal the signal S5 414 is shown in Graph 424th S5 is a signal of frequency f, where the duration of the signal is τ. If there is no phase shift in the signal, S5 414 is a disappearing signal.

If a signal of frequency f has passed through the frequency ^{filter, it is} checked by the embodiment described above whether this signal has a phase jump. This prevents, for example, that a broadband "jammer", which also a

Signal of frequency f emits the consumer activated, since it is unlikely that this signal has a phase jump or phase jumps in a known sequence. The ^¬ ser state thus occurs when using several frequencies then when all of the frequencies have this phase jump at the same time.

5 shows a surface acoustic wave filter circuit (SAW filter circuit). An SAW filter circuit provides other exemplary form of detecting whether a signal having a certain frequency Fre ^¬ and a phase jump is.

There is the evaluation circuit for a particular Fre ^acid sequence consists essentially of two parallel-connected surface-chenwellenfiltern (SAW filters) 502, 504 and two transistors 506, 508th A frequency ^pattern received by a receiving means, such as an antenna, is fed into the two inputs 510 and 512 of the SAW filters 502, 504. The SAW filters 502, 504 are designed so that both filter out a signal with a certain frequency f from the received frequency pattern. Signals with a frequency different from f can not pass through the SAW filters 502, 504. In addition, the lengths of the two SAW filters 502, 504 are designed such that the difference of the signal propagation times for signals with the frequency f through the two SAW filters 502, 504 corresponds to a phase jump of 180 ° and a time delay of τ = n / (2f ) corresponds. Here n is a nonnegative integer and f is the frequency of the signal.

The two transistors 506, 508 are now connected to the outputs of the SAW filters such that the two outputs of the SAW filters 502, 504 AND are combined or multiplied. As described above, a signal is generated which has the frequency f and has a time length of τ.

In a preferred embodiment, self-blocking MOSFET transistors are used as transistors 506 and 508. These can be set with the aid of programming, for example in the manner of an EPROM, so that a voltage at the gate causes the transistor to conduct (active) or not (passively). For this purpose, the MOSFET transistors have an insulated auxiliary electrode, the so-called floating gate. When mieren Program ^¬ is applied an increased voltage, so that charged by the tunneling effect, the floating gate. As a result, the drive voltage, at which the semiconductor switch switches, shifts. When deleting by known methods, eg by means of UV light, the previously applied electrode leaves recharging the semiconductor switch and the transistor can then be reprogrammed.

In the active case, the semiconductor then acts as a rectifier (half-wave operation in a self-locking basic circuit), which allows current flow during the positive half-wave of the gate voltage.

The signal generated by the SAW filter circuit is fed via the outputs 514, 516 to an evaluation circuit as described below.

FIG. 6 shows a frequency evaluation module. In the embodiment shown in ^FIG. 600, a plurality of SAW filter circuits 602, 604, 606, 608, 610 and ⁶⁰ are provided in a frequency evaluation module

612, connected in a known manner so that the filter scarf ^¬ lines are logically AND and OR linked.

As mentioned above, MOSFET transistors may be e.g. programmed in the manner of an EPROM so that a voltage at the gate causes the semiconductor to conduct (active) or not (passively). According to the embodiment illustrated in FIG. 600, for the SAW filter circuits 602, 606 and 610, the MOSFET transistors included therein are programmed to be active.

The third ANDW filter circuits 604 of the AND link is programmed in the illustrated embodiment such that it conducts in any case - regardless of the applied signal. To emphasize the difference between the SAW filter circuits 602, 604 and 606, the symbol f2 was crossed out in 600 because the SAW filter circuit 604 is conducting in each case. The SAW filter circuits 608 and 612 of the OR links are programmed to always disable. In order to ^{emphasize the} difference between the SAW filter circuits 608, 610 and 612, the symbols f1 and f2 have been crossed out in 600, since the SAW filter circuits 608 and 612 also block when a signal with the frequency f1 or with the Frequency f3 is detected.

The illustrated in FIG 6 inventive arrangement of the SAW filter circuits 602, 604, 606, 608, 610 and 612 and the programming described Now, lead to the fact that in Ruhezu ^¬ stand without a received frequency pattern, a capacitor C 620 via a high resistance R 618 by a Voltage ^¬ Source U _b att 616, such as a battery or an accumulator tor) is charged.

In a frequency pattern received by the antenna 614, it is detected by means of the SAW filter circuit 602 as described above, whether the frequency band contains the signal of the frequency fl and whether this signal has a phase jump. Similarly, the SAW filter circuit 606 detected as above ^¬ be written, if the frequency band containing the signal of frequency f3, and whether this signal has a phase jump. Furthermore, SAW filter circuit 610 detects, as described above, whether the frequency band contains the signal with the frequency f2 and whether this signal has a phase jump.

If the received frequency pattern contains signals with the fre ^¬ frequencies fl and f3, which also contain a phase shift, then the SAW filter circuits 602 and 606 through

(and also SAW filter circuit 604). Also, if the received frequency pattern does not include a signal of frequency f2, then SAW does not switch through filter circuit 610 (and also SAW filter circuits 608 and 612, which never turn on). This will, upon detection of a frequency pattern that Signa ^¬ le with the frequencies fl and f3 and does not contain the signal having the frequency f2, the battery voltage on the output voltage Uout ^¬ 622 for the duration τ switched through.

The frequency module shown in FIG. 600 is programmed to detect the frequency pattern with signals of frequency fl and f3 and not f2. To detect specifically ^¬ nalkombination this Sig OFW Filterschaltun- gen 604, 608 and 612 are not required in principle.

However, the embodiment shown in 600 has the advantage that the same frequency evaluation module could detect a different signal combination by reprogramming.

7 shows a block diagram of an interconnection of frequency modules for evaluating the time sequence of the detected frequency patterns.

This interconnect includes the frequency evaluator modules 702, 704, and 706, each of which, as exemplified above, detects a particular frequency pattern.

If the frequency evaluation module 702 detects the frequency pattern assigned to it, then the voltage U _ba t 728 is switched through to the ^{output of} the frequency ^{evaluation module} 712. The voltage applied to the output 712 is turned on by the transistors 708 and 710 and charges the capacitor 714.

If the frequency evaluation module 704 detects the frequency pattern assigned to it, then the voltage U _ba t 728 is switched through to the ^{output of} the frequency ^{evaluation module} 718. The voltage applied to the output 718, however, is only switched through the transistor 717 to the capacitor when the capacitor 714 in the time that has a frequency pattern by the Fre ^¬ quenzauswertemodul 704, not discharged between the detection of a frequency pattern by the Frequenzauswertemodul 702 and the detection.

The capacitor capacitance is selected such that the Ent ^¬ charging time of the capacitor to the time interval corresponds to two successive ^¬ frequency pattern. That is, only when 702 and 704 detect frequency patterns, the capacitor 720 is charged.

Now detects the Frequenzauswertemodul 706, it zugeord ^¬ designated frequency pattern, then the voltage U t _ba is switched through to the output of the Frequenzauswertemoduls 726,728. However, this is only forwarded if the capacitor 720 has not discharged in the time which elapsed between the detection of a frequency pattern by the frequency evaluation module 706 and the detection of a frequency pattern by the frequency evaluation module 704.

Only when 702, 704 and 706 frequency patterns in the timely sequence detect frequency patterns is the voltage 728 turned on by the transistor. This signal can then serve to activate the consumer.

Claims

claims

An apparatus for activating an electrical load (102) comprising: - receiving means (104) for receiving a time sequence of frequency patterns (122), wherein each frequency pattern (110) comprises a combination of signals (112) with particular frequencies (118) and wherein each signal (114) of the combination of signals (112) has a phase jump (118);

- Detection means (106) for detecting whether contained in a frequency pattern (110) combination of signals

(112) associated with certain frequencies (116) to the electrical load (102); - Detection means (124) for detecting whether each signal

(114) has the phase jump (118) from the determined combination of signals (112);

- Detection means (126) for detecting whether the temporal sequence of the frequency pattern (114) is associated with the electrical load (102);

- means for activating (108) the electrical load (102) in the event of detection.

2. A device for activating an electrical consumer (102) according to claim 1, comprising:

- means for generating a second signal (416) and a third signal (412) from each signal (114) from the combination of signals (112);

- means for generating a fourth signal (410) from the second signal (416) by delaying the second signal (416) by a certain period of time;

- means for superimposing the third signal (412) and the fourth signal (410); - Means for generating a fifth signal (414) by superposition of the third signal (412) and the fourth signal (410), wherein the fifth signal (1414) for activation ^¬ tion of an electrical consumer (102) is used.

3. A device for activating an electrical load (102) according to claims 1, or 2 with:

- a frequency filter for detecting a signal (114) having a certain frequency from the combination of signals (112);

- A signal divider for generating the second signal

(416) and the third signal (412) from the signal (114);

a phase shifter and a time delay element

(406) for generating a fourth signal (410) from the second signal (416);

- A signal mixer (408) for superposition of the third signal (412) and the fourth signal (410) and gene ^¬ tion of the fifth signal (414).

4. An apparatus for activating an electrical load (102) according to any one of claims 1 to 3 with:

- a first surface acoustic wave filter (SAW filter) (502) for detecting a signal (114) having a certain frequency from the combination of signals (112) and for generating the third signal;

- a second SAW filter for detecting the signal (114) having the particular frequency from the combination of signals (112) and generating a third signal, the second SAW filter (504) being connected in parallel with the first SAW filter (504);

- means for generating a fourth signal by time delaying the second signal by using the first SAW filter (502); two transistors (506, 508) for superimposing the third signal and the fourth signal, the transistors (506, 508) being associated with the first and second SAW filters (502, 504) such that the fifth signal is the sum of the third signal and fourth signal.

5. A device for activating an electrical load (102) according to one of claims 1 to 4, characterized in that are provided as consumer radio devices.

6. An apparatus for activating an electrical load (102) according to any one of claims 1 to 5, characterized in that the receiving means (104), the detection means (106, 130, 132) and the means for activating (108) of

Consumer (102) are integrated in an electronic module.

7. A device for activating an electrical consumer (102) according to any one of claims 1 to 6, characterized in that the means for activating (108) of the consumer ^¬ (102) are used to the consumer (102) in the To put to rest.

8. A method for activating an electrical load (102) comprising the following steps:

- Receiving a time sequence (122) of frequency patterns, wherein in each case a frequency pattern (110) a Kombi ^¬ nation of signals (112) having certain frequencies (116), and wherein each signal (114) from the combi ^¬ nation of signals has a phase jump (118);

Detecting whether the combination of signals (112) contained in a frequency pattern (110) with certain frequencies zen (116) associated with the electrical load (102);

- detecting whether each signal (114) from the particular combination of signals (112) has the phase jump (118);

- Detection of whether the temporal sequence of the frequency pattern

(114) associated with the electrical load (102);

- Activation (108) of the electrical load (102) in the case of detection.

9. A method of activating an electrical load (102) according to claim 8, comprising the steps of:

- generating a second signal (416) and a third signal (412) from each signal (114) from the combination of signals (112);

- Generating a fourth signal (410) from the second signal (416) by time delay of the second Sig ^¬ nals (416) by a certain period of time;

- superposition of the third signal (412) and the fourth signal (410);

- Generation of a fifth signal (414) by superposition of the third signal (412) and the fourth signal (410), wherein the fifth signal (1414) for activating the one electrical load (102) is used.

10. A method for activating an electrical load (102) according to claims 8 or 9, comprising the steps of:

- detecting a signal (114) having a certain frequency from the combination of signals (112) through a frequency filter;

- generating the second signal (416) and the third signal (412) from the signal (114) by signal division; - Generation of a fourth signal (410) from the second signal (416) by means of time delay and Phasenverschie ^¬ tion of the second signal (416);

- Overlaying the third signal (412) and the fourth signal (410) by means of mixer (408) and generating the fifth signal (414).

11. A method for activating an electrical load (102) according to one of claims 8 to 10, comprising the steps of: - detecting a signal (114) having a specific frequency from the combination of signals (112) by means of surface wave filters (SAW filters) ( 502) and generating a third signal;

- Detecting the signal (114) with the specific frequency from the combination of signals (112) by means of a second SAW filter (504) and generating a third signal, wherein the second SAW filter (504) to the first SAW filter (504) connected in parallel is;

Generation of a fourth signal by time delay of the second signal and by use of the first SAW

Filters (502);

- Overlaying the third signal and the fourth signal by means of two transistors (506, 508), the Transisto ^¬ ren (506, 508) with the first and the second OFW filters (502, 504) are linked so that the fifth signal the sum of the third signal and fourth signal.

12. A method for activating an electrical load (102) according to any one of claims 8 to 11, character- ized in that as a consumer radio devices are vorgese ^¬ hen.

13. A method for activating an electrical load (102) according to one of claims 8 to 12, characterized indicates that the receiving means (104), the detection means (106, 130, 132) and the means (108) for activating the consumer (102) are integrated in an electronic component.

14. A method for activating an electrical load (102) according to any one of claims 8 to 13, characterized ge ^¬ indicates that the means for activating (108) of the consumer (102) are used to the consumer (102) in the idle state offset.

15. A computer program product having computer executable In ^¬ constructions to a method according to any one of claims 8 to 14 run.