DE3918131A1 - Receiver for coded EM pulse transmissions - Google Patents

Abstract

A receiver for pulse coded electromagnetic transmissionsa is used as the basis of a remote controller. The system has a power supply (150) and a high frequency receiver (350) that consists of an amplifier/mixer, high frequency oscillator, demodulator and signal amplitude regulator. In addition the system has a decoder unit (250) that is coupled to a selector unit. The basis of the unit is an EEPROM chip that can receive a specific transmission pattern that is retained as a reference for comparison with later transmissions.

Description

The present invention relates to a receiver for the Emp catch coded electromagnetic pulses, which essentially from a current / voltage supply, an antenna, an integrated receiver with HF and IF amplifier stages and a mixer for intermediate frequency generation, a demodule lator, a signal amplitude control, a decoding unit with Code selection circuit and an input / output circuit (interface) consists.

According to German patent application P 37 41 324.4, to which the present application has an additional relationship the receiving part one in a wide frequency range oscillating oscillator and the resonant circuit of the antenna has a trimming capacitor, the coupling of the Received signals via a capacitive divider that is connected to ground via an RF capacitor.

The object of the aforementioned patent application was a receiver with the above characteristics (as well to create a corresponding transmitter), which is cheaper and should be able to be produced in smaller dimensions, whereby maintain functional safety, if possible still ge should be increased.

This additional application also pursues the goal of a production of a receiver with small as cheap as possible Dimensions, with a focus on increasing the functional reliability, especially the input sensitivity speed of the receiver is placed on the decoding part ease of use is important.

The receiver according to the present invention is almost correct all features with the be in the main application mentioned written recipient, unless expressly stated here is based on other or additional features. So far the content of the main application will be considered in this application  message recorded.

As already described in the main application, serve suchi ge receiver for example for the control of garage doors, the receiver receiving a corresponding encoded pulse receives a transmitter, identified and then the ge executes the desired function (output function), e.g. to open or closing a garage door or actuation of the engines and facilities.

It has been found that with unfavorable transmission or Reception conditions the output functions of the receiver only can then be triggered when the transmitter is a relative short (a few meters) from the receiver. This applies ins especially if there are any electromagnetic worlds len shielding parts between transmitter and receiver. In this respect, there is a need for the range of the Sen to enlarge the receiver system. However, the Sen power cannot be increased arbitrarily, this being at all This is mainly due to the fact that ferrite antennas are often used can not radiate enough power, and unwieldy staff antennas are reluctant to be used in such systems.

As a result, the present invention has the object reasons, a receiver with the features mentioned above to create which with the simplest possible structure, the one allows inexpensive production in small dimensions still has a higher input sensitivity, so that the realm the width of the transceiver system even under unfavorable conditions is sufficiently large, e.g. on the order of 10 to 50 m or more.

This object is achieved in that behind the demodulator a low for the useful signal from the RF receiver circuit pass filter is provided.

The useful signal emerging from the RF receiver circuit is  relatively noisy. After demodulation, this ver then signal rushed to certain fixed voltage values be set, due to the poor signal / noise ratio errors can easily occur, the level Setter actually sends impulses of the noise signal converts or transmitted impulses are lost in noise, which are implemented incorrectly, so that the Receiver logic to be processed signal not with the on set code matches the corresponding receiver radio tion is not triggered.

This bad signal-to-noise ratio is caused by insertion a low-pass filter immediately behind the demodulator Lich improved so that the useful signal more clearly from the noise is to be distinguished, and the error rate in the implementation of the Useful signal in logical signals is drastically reduced. The Low pass filters remove practically all higher frequencies Noise components whose frequency is above the cutoff frequency of the Filters are, which in turn is higher than the Fre sequence of the useful signal.

It is provided according to the invention that the low-pass filter has at least two RC elements. This double filtering brings a noticeable effect in terms of error reduction tion and the associated increase in range. The Sensitivity of the recipient and the dependent range Width can be increased further if according to a particular Ren embodiment the low-pass filter an active gain having. This results in a particularly steep-sided Low pass characteristics. It is particularly advantageous if for the reinforcement already existing components of the receiver used, e.g. the input amplifier the level conversion circuit.

The reception properties are further improved by if according to a preferred embodiment between anten resonant circuit and RF receiver resonant circuit a preamplifier is provided. The properties of the HF / IF  Amplifier and mixer part much better used and that Signal reaching the demodulator points at weaker RF on a larger amplitude from the outset.

In the sense of the simplest possible structure, the preliminary ver stronger a transistor, the signal coupling on Collector of the transistor is done.

There is a resistance to on between the base and the collector set the operating point of the transistor provided.

It is also useful if between operating voltage leadership and collector an ohmic resistance is provided. Of course, an inductive resistor can also be used det, which allows a greater gain.

The above structure of a preamplifier is relatively one fold and causes only very small additional costs, which by the Increase the input sensitivity of the receiver without more will be made up for. According to another expedient The decoding unit also has an embodiment of the receiver an EEPROM on a microprocessor. This enables the Automatically detect transmitter identification without this on the emp catcher must be set. In particular, it can also longer bit sequences are transmitted and processed so that e.g. when using so-called check or check bits Errors can be corrected automatically and already the a single reception of a correct signal sequence is sufficient to trigger the receiver function. Without using suchi As a rule, multiple test options are corrected ter receipt of the command signal sequence for triggering the emp catcher function required. This reduction to one too correctly received command signal sequence contributes to the increase range, especially if the corresponding Sen which is operated from moving objects (e.g. a car).

It is provided according to the invention that the EEPROM on meh rere different transmitters and output functions per  is grammable.

The invention is now with its features, advantages and possible applications based on a preferred embodiment and the associated figures. Show it:

Fig. 1 is a block diagram of a receiver,

Fig. 2 is a part of the circuit diagram of the receiver and

Fig. 3 shows the rest of the circuit diagram of the receiver.

The block diagram of Fig. 1 largely coincides with the Fi gur of the main application P 37 41 324.4, but the RF receiver under reference number 375 has an additional part, namely the preamplifier, and the block labeled "Gain control and demodulator" contains an additional low-pass filter under the reference number 385 . The NF deco can have an EEPROM 265 instead of a DIL switch and part of the programming circuit.

As can be seen in FIG. 2 on the antenna circuit 360 by comparison with the corresponding FIG. 4 of the main application, the resonant circuit 370 of the antenna is practically no different from the previous model. However, the output of the antenna resonant circuit 370 is not given directly to the RF input of the mixer I 4 , but is preamplified via a transistor T 41 , which is connected to the RF input of the mixer via the capacitor C 45 . The operating point of the transistor T 41 is set via the resistor R 42 , an inductive load resistor L 42 is connected between the operating voltage supply and the collector of the transistor, but this can also be replaced by a corresponding ohmic resistor. In the present case, too, the received signal is coupled out before reaching transistor T 41 via a capacitive divider C 42 // C 43 , C 44 , which is connected to ground via capacitor C 44 .

In the area between the demodulator 380 and the level converter 390 , in comparison with that in FIG. 4 of the main application in the present embodiment according to FIG. 2, a low-pass filter 385 has been inserted, which essentially consists of two RC elements R 2 , C 3 ; R 3 , C 4 exists. The operational amplifier I 2 of the level converter is used directly for active amplification during filtering, so that the desired filter curve of the selected filter type is reliably achieved.

FIG. 3 shows the remaining part of the circuit diagram of the receiver, the main difference from the corresponding FIG. 5 of the main application being that the DIL switch 260 is replaced by three EEPROMS. An EEPROM can take over all the functions of the DIL switch, can also be programmed on several different hand transmitters with different coding and also on several output functions and thus also replaces the code selection circuit with a new, intelligent and component-saving, fully electronic one Solution. For programming to a specific transmitter and a specific function, the EEPROM is brought into a programmable state via a pushbutton switch or the like, while in normal operation it only detects and evaluates the pulses from transmitters and releases corresponding functions.

The exact values of individual capacitors, resistors and In ductivities are described above in the pre-registration The specified recipient only changed in individual cases.

Various transmitter identifiers and also codes for output functions can be stored in the EEPROM either by setting a specific operating state of the EEPROM, which codes are linked to the transmitter identifiers via the associated microprocessor I 3 . In the model of the microprocessor I 3 provided here, eight different switching outputs with up to 16 different output functions per switching output can be controlled directly by the microprocessor. By connecting a decoder (not shown in the figures), however, the number of possible switching outputs can be increased, for example, to 2 ⁸ = 256 by linking the various output states of the microprocessor. The EEPROM also enables certain functions and transmitter IDs to be deleted.

In the embodiment shown in FIG. 3, a total of three EEPROMS are provided in the field identified by 260 , of which, however, the EEPROM designated by I 104 would in principle suffice to include the DIL switch 260 shown in FIG. 5 of the main application and also to replace the other elements of the downstream output circuit. Several EEPROMS are only intended for the purpose of increasing the number of detectable transmitter IDs. In addition, push button switches S 1 , S 2 are shown in FIG. 3, which are only switched to enter or delete a specific transmitter identifier in one of the EEPROMS.

This has the advantage, moreover, that a transmitter can receive any coding, unknown to the user, which consists of a series of, for example, 22 or 40 bits. By actuating the transmitter in the vicinity of the receiver and at the same time actuating one of the learning buttons S 1 , this coding is then stored in the associated EEPROM, and a specific output function can be assigned at the same time.

With the delete key S 2 , certain transmitter codes and / or output functions assigned to them can in turn be deleted from one of the EEPROMS.

In addition, the receiver can also be linked to a PC (small computer), the microprocessor I 3 passing through the received signals for further testing and processing on the PC.

By using such a PC (small computer), the number of stored transmitters with access authorization as well as the number of functions to be controlled, including the linking of transmitter identifications and functions, can be expanded practically indefinitely. In such a case, the EEPROM expediently contains only an identifier which allows the microprocessor I 3 to establish the connection to the PC.

Claims (12)

1. Receiver for coded electromagnetic pulses, consisting of:

• a) a current / voltage supply ( 150 ),
• b) an RF receiving part ( 350 ) consisting of
• 1) an RF input circuit (antenna circuit, 360 ),
• 2) an RF / IF amplifier and mixer section (I 4 )
• 3) an RF oscillator ( 340 )
• 4) a demodulator ( 380 ),
• 5) a signal amplitude control circuit and level conversion ( 390 )
• c) a decoding unit ( 250 ) with code selection circuit ( 260 ),
• d) an interface (input / output circuit, 850 ), where
• e) the receiving part ( 350 ) has an oscillating oscillator ( 340 ) rich in a wide frequency range, and wherein
• f) the resonant circuit ( 370 ) of the antenna ( 360 ) has a balancing capacitor (C 42 ) and the coupling of the received signal Emp via a capacitive divider (C 42 // C 43 , C 44 ) and this divider via a capacitor (C 44 ) is connected to ground in terms of HF, in accordance with patent application No. 37 411 324.4,
  characterized in that a low-pass filter ( 385 ) is provided behind the demodulator ( 380 ) for the useful signal from the RF receiver circuit.

2. Receiver according to claim 1, characterized in that the low-pass filter ( 385 ) has at least two RC elements (R 2 , C 3 ; R 3 , C 4 ). 3. Receiver according to claim 1 or 2, characterized in that the low-pass filter ( 385 ) has an active gain (I 2 ). 4. Receiver according to one of claims 1 to 3, characterized in that a preamplifier ( 375 ) is provided between the antenna resonant circuit ( 370 ) and the RF receiver input. 5. Receiver according to claim 4, characterized in that the preamplifier ( 375 ) has a transistor (T 41 ) and that the signal is coupled out at the collector of the transistor (T 41 ). 6. Receiver according to claim 5, characterized in that between the base's and collector of the transistor (T 41 ) an opposing stand (R 42 ) is provided for setting the operating point. 7. Preamplifier according to claim 5 or 6, characterized in that an ohmic resistor (L 42 ) is provided between an operating voltage supply and the collector of the transistor (T 41 ). 8. Receiver according to one of claims 1 to 7, characterized in that the RF receiving part ( 350 ) downstream decoding unit ( 250 ) has at least one EEPROM ( 265 ). 9. Receiver according to claim 8, characterized in that the EEPROM ( 265 ) on certain transmitters and output functions of the receiver is permanently programmable. 10. Receiver according to claim 8 or 9, which for the decoding tion of the signals has a microprocessor, thereby ge indicates that the receiver has at least eight switches has gears. 11. Receiver according to claim 10, characterized in that the Microprocessor is connected to a decoder, which the Number of switching outputs increased. 12. Receiver according to one of claims 8 to 11, characterized ge indicates that it has a connection (interface) for egg NEN PC has.