DE19851002A1 - Electronic device with identification or sensor function for telemetry varies resonant frequency of circuit including resonator, matching circuit and transmitter unit - Google Patents

Abstract

The device includes a storage component for storing HF energy. A capacitive, inductive or resistive identification and/or sensor component is included in a circuit that varies the resonant frequency of an arrangement comprising the storage component, matching circuit and transmitter unit, based on an identity or measured parameter. The storage component may be a resonator whose resonant frequency is shifted using the identification and/or sensor component. The storage component may alternatively by one or more delay lines or an acousto-electronic device.

Description

The invention relates to an electronic assembly with identification and / or sensor function, the at least one vibratable component for Contains RF energy storage.

It represents an arrangement for determining physical quantities in which the information about the identification or the sensor function for transmission is converted into an RF signal. The HF memory device ment has the task of temporarily storing the RF energy and deliver the response signal. The response signal can be obtained wired or over a radio link. The electronic The module itself works passively and does not require its own to function electrical power supply. As a hybrid arrangement, it enables separate optimization of identification and / or sensor component, the oscillatable storage element for the RF energy and the antenna.

Telemetry sensors are used in many areas of technology. she enable the acquisition of physical quantities and identification from technical objects to difficult to access or aggressive ones  Places marked by environmental conditions as well as changeable places Objects.

Various arrangements for telemetric are in the prior art Acquisition of physical quantities known. In particular, elec tromagnetic transponders or acoustoelectronic systems are used. Conventional systems based on electromagnetic transponders are possible need only short polling distances or require an energy source Sensor.

DE 44 24 773 A1 describes a telemetry system with a central interrogation sta tion, which has a larger number of spatially distributed sensor stations NEN is assigned, which can be selectively activated and their measuring devices and Use signal processing arrangements with surface acoustic waves end components and electronic circuits. At This arrangement consists of those between the interrogation station and the sensor stations bidirectionally via a common transmission medium averaging information from signal sequences in which individually coded Passwords of the same duration and the same number of word elements Form basic patterns and repetition frequencies of identically coded basic mu represent specific information for measured values.

These are conventional systems based on Transponders work. You are therefore on short query distances limited if they work passively or require their own energy source at the measuring point.

According to DE 44 13 211 A1, passive telemetric sensors are based on known acoustoelectronic resonators.

By switching various resonators on and off, they become identifiers tion enables. The disadvantage here is that the limited number of  different resonators in a frequency band the number of under different identification marks is limited.

By influencing the acoustoelectronic component with physi Kalischen sizes such as temperature, mechanical tension u. Ä., that is It is possible to measure these sizes. However, since the component is directly the physi is exposed to calic size, it is also a heavy burden exposed what the lifespan and duration of maintenance-free intervals restricted.

WO 96/33 423 describes an arrangement for passive remote monitoring Sensor technology presented, in which a switched sensor changes due to its impedance the reflection factor of surface wave arrangements changed. That from the surface wave arrangement after an excitation signal returned by RF energy contains the sensor information as Change in amplitude. As a result, the sensor arrangement operating in this way is relative insensitive, has a low accuracy and is difficult to tell calibrate rig.

The operation of known sensors is based on the fact that a physical Measured variable through different arrangements in changes in capacity, Inductance or electrical resistance is converted. The Changes in electrical properties can be made by electronic Circuits are evaluated. The electronic circuits must be in the be direct electrical contact with the sensor and convert the changes electrical properties into transferable and evaluable Signals around.

With the known acoustoelectronic arrangements is at separate Transmission and sensory components only the transmission of Information in the form of amplitude changes possible.  

The invention is based on the object of specifying an arrangement with the data of analog sensors as a frequency change over a radio link or can be transmitted by wire without an energy source is required on the sensor.

According to the invention, the object is achieved with an arrangement the characterizing features of claim 1.

Advantageous refinements are specified in the subclaims.

The arrangement preferably works with one or more resona gates based on surface acoustic waves or acoustic Bulk waves or with other vibrating RF storage devices elements (e.g. cavity resonators) that (with a suitable antenna and) are connected to a suitable antenna via a matching network. Here, the adaptation network is switched so that at least one Element of the adapter circuit as an identification and / or sensor element Defi the resonance frequency or the parameters of delay lines influenced.

The electronic circuit consists of inductors, capacitors and / or electrical resistances. The components are chosen so that one or several depend on the physical quantity to be measured. For the Identification, the electronic circuit consists of capacitors, inductors vities and / or electrical resistances, individually or in combination that contain information about the identities. This results in the Shift the resonance frequency depending on the to be determined the physical size or identity. The resonance frequency is in is determined by an evaluation unit and the result is determined therefrom.

It is particularly advantageous that it is due to the combination according to the invention nation from passive telemetric high-frequency energy storage devices and conventional capacitive, inductive or resistive sensors  or identification arrangements succeed, the data in the form of a frequency transfer over a radio link or wired. By separating the transmission and identification or sensor component, it is possible to separate the respective components optimize, based on existing, optimized sensors, identiflzie tion components and HF energy storage components can be.

It is also advantageous that the transmission component does not meet the requirements conditions of the measurand is exposed. This will also when used under unfavorable environmental conditions achieved high long-term stability. Another advantage is that the measurement signal as a frequency shift high sensitivity and accuracy.

In addition, through the use of double and / or more Special HF memory components Influences of cross-sensitivities (e.g. against temperature, humidity and the like) and disturbances in the transmission channel avoided.

The invention is explained in more detail below using an exemplary embodiment tert.

In the accompanying drawing:

Fig. 1 shows an example of an arrangement with Oberflächenwellenreso nator as HF memory device, wherein the capacitance of one measured variable is dependent,

Fig. 2 shows an example of an arrangement in which the inductance of one measured variable is dependent

Fig. 3 shows an arrangement with two resonators,

Fig. 4 shows an example of an identification system.

In the illustrated in Fig. 1 and 2 embodiments of the resonator (4) is ty with the antenna (1) via a matching network consisting of a capaci and connected to an inductor. The surface wave resonator consists of an interdigital transducer ( 7 ) and reflectors ( 6 ) which are arranged on a piezoelectric substrate ( 5 ). The excitation ( 10 a) can take the form of a narrow-band signal such as sine burst or chirp.

In Fig. 1, an arrangement is shown in which a capacitive sensor (2) is connected with an inductance (8). Fig. 2 explains an arrangement in which the adapter network is formed by an inductive sensor ( 3 ) and the capacitance ( 9 ).

The frequency-dependent impedance of the matching network makes it possible to vary the frequency at which the maximum energy can be stored in the resonator. The impedance depends on the capacitance and the inductance. If at least one of these two variables is changed, the resonance frequency of the module changes. The narrow-band frequency response ( 10 b) can be recorded wirelessly to obtain measured values.

Fig. 3 shows an embodiment with two resonators. Between the antenna ( 1 ) and the resonators ( 4 a) and ( 4 b) is the matching network of inductivities ( 8 a) and ( 8 b) and a capacitive sensor ( 2 ). By changing the capacity in the matching network, the difference in the resonance frequencies changes, which can be detected wirelessly.

Fig. 4 shows an embodiment for identification. Between the antenna ( 1 ) and the similar resonators ( 4 ) is the matching network consisting of inductors ( 8 a), ( 8 b) and capacitances that can be switched on by switches ( 11 ). The different capacitance values ( 9 a), ( 9 b), ( 9 c) generate different resonance frequencies that can be detected wirelessly. This enables clear identification.

REFERENCE SIGN LIST

1

antenna

2nd

capacitive sensor

3rd

inductive sensor

4th

Resonator

4th

a resonator

1

with several resonators

4th

b resonator

2nd

with several resonators

5

piezoelectric substrate

6

reflector

7

Interdigital converter

8th

Inductance

8th

a inductance

1

with several resonators

8th

b inductance

2nd

with several resonators

9

capacity

9

a capacity

1

upon identification

9

b capacity

2nd

upon identification

9

c capacity

3rd

upon identification

10th

a excitation signal

10th

b response signal

11

switch

Claims (5)

1. Electronic assembly with identification and / or sensor function, which contains at least one component for storing RF energy, characterized in that at least one capacitive, inductive or resistive identification and / or sensor component is integrated in a circuit device, which changes the resonance frequency of the arrangement consisting of memory component, adapter circuit and transmission unit, depending on an identity or measured variable. 2. Electronic assembly according to claim 1, characterized in that that a resonator is arranged as the memory component, the resonance thereof frequency through the circuit using the identification and / or Sensor component is moved. 3. Electronic assembly according to claim 1, characterized in that the memory device from an arrangement of two or more Resonators exist. 4. Electronic assembly according to claim 1, characterized in that the memory device consists of one or more delay lines exists, the characteristic frequency defined depending on one Identity or measurand is changed.   5. Electronic assembly according to one of the preceding claims, characterized in that an acoustoelectronic as the memory component cal component.