HU197816B - Data transmission unit for detecting location of persons, objects in a given range - Google Patents

Abstract

A data transmission and monitoring/controlling system comprising transmitters 5 and receivers, in which district or local receivers contactable by local networks receive, evaluate and/or transmit signals of code transmitters placed in an area defined by an antenna or loop, the code senders operating with random periodicity and transmitting in FM code of constant length having at most three conditions or states. A gate 2 is connected between an oscillator 1 and a frequency synthesiser 3 which controls a switch 4 which frequency modulates a transmitter 5. Modulation information signals are provided via code transmitters 6 and 7. Gate 2 is controlled by a random generator 10, an enable circuit 8 and an inhibit circuit 9. The gate 2 and switch 4 are described (Figure 2). The transmitter 5 and the receiver are described (Figures 3 and 4) respectively. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to data transmitting apparatus for determining the location of persons, objects, a coding unit, a signal processing unit connected to an output thereof and a transmitter having a known transmitter antenna connected to the output of the processing unit and a receiver antenna inductively connected to the transmitter. , by means of which the change of position, movement or even the condition of a person or object in a given area can be checked, observed, and possibly recorded.

There are a number of areas in transport, in various areas of industry, and in particular in underground mines, where work organization, safety or, if appropriate, other considerations are necessary, and the need to identify persons or objects there at all times, or receive sensory or warning signals from them.

To accomplish such tasks, data transmission equipment comprising various mobile code transmitters and stationary receivers is used. Some use a transmitting ultra-shortwave transmitter or receiver as a transmission path. Such examples are disclosed in GB 2,057,818 and GB 2,084,430, respectively. However, they are complicated, cannot be broadcast everywhere, and costly. An important aspect of data communication equipment, for example, is the wireless connection of transmitters and receivers, such that data transmission is independent of service and handling personnel.

Wired signaling can also be accomplished by connecting to other existing wires, such as a power cable or power cable, and transmitting signals in duplex or simplex mode. However, this arrangement does not allow the transmitter to move freely and unrestrictedly, and has the further disadvantage that if there is a large number of persons or objects to be identified in a given area, the signal to be identified will be long and the query cycle will be long. These devices are very energy intensive and expensive to use, even in aggressive environments, due to the need for other forms of protection.

It is an object of the present invention to provide a portable data transmission apparatus comprising a transmitter having a simple construction, a low power consumption and a multiplicity of encodings, but with virtually continuous control.

The data transmission apparatus according to the present invention is essentially based on the discovery that if a signal is not scanned at a predetermined period of time, but is triggered by a random signal generator generating a stochastic signal and the detection is very short, virtually continuous information can be obtained. without power consumption.

The present invention thus provides data transmission apparatus for determining the location of persons, objects in a given area, a transmitter having a known transmit antenna connected to an encoder unit and a receiver antenna connected to the output of the signal processing unit and a receiver antenna inductively connected to the transmitter. wherein the signal processing unit comprises an oscillator which is connected to a controlled gate circuit as a clock generator and connected to a switching circuit while the first input of the controlled gate circuit is connected to a random generator and its first output is via a frequency generator generating a three-state FM code. connected to its first input, which is the first input of a logic Gate Circuit having a further input on the one hand and a multiplexer on the other connected to the output of the switch circuit and connected to the counters outputs of the multiplexer, the data inputs are fixed to an encoder generating a code specific to the person or object and the logic gate circuit output is connected to the transmitter. the receiving antenna is a shell or loops formed of wire laid in the space under test.

In order to not only trigger the detection by a stochastic variable signal, it is preferably an embodiment of the invention that the controlled gate circuit is also provided with a second input to which an external transmit start circuit is connected.

In order to ensure that only one object is detected at a time for several objects to be measured, it is advantageous that the controlled gate current is provided with an additional third input, to which a transmit-blocking circuit is connected, with a fixed but adjustable encoder is provided with a numerical wheel, a multi-digit encoder coupled to the controlled encoder by a microswitch.

In an embodiment of the invention, the controlled gate circuit comprises first and second ES gates, one of which inputs is interconnected to the oscillator and the second input of the first AND gate forms the first input of the controlled gate circuit and is still connected. coupled to one input of a first NO gate, while the other input of the same NO gate is connected to the other input of the second AND gate to form a second input of the controlled gate circuit, and the first NO gate output has a switch circuit counter connected to the RESET input, and the outputs of the first and second AND gates are connected to an input of a third AND gate, which3

-319 ⁷⁸¹⁶ has an input of the third gate circuit is controlled via the first input of another inverter, while the output of the third AND gate is a gate-driven output circuit.

The data transmission apparatus according to the invention will now be described in more detail with reference to an exemplary embodiment, in the accompanying drawings. The

Fig. 1 is a block diagram of the transmitting apparatus of the data transmission apparatus according to the invention, a

2 shows a more detailed embodiment of the signal processing unit, while FIG

Figure 3 shows one. is a block diagram of an exemplary embodiment of a substantially self-known transmitter, a

4 shows an exemplary embodiment of the receiver.

Figure 1 is a block diagram of the transmitting apparatus of the data transmission apparatus according to the invention. The figure shows an oscillator connected to a controlled gate circuit 2 and a switching circuit 4 as a clock generator. The controlled gate circuit 2 is provided with three inputs as a control input, with the first input connected to a random signal generator 10, the second input connected to a transmit start circuit 8 and the third input connected to a transmission enable blocking circuit 9. The output of the controlled gate circuit 2 is connected to the switching circuit 4 via a frequency synthesizer 3. The switching circuit 4 is further provided with two inputs, one of which is connected to a fixed but adjustable code transmitter 6 and the other input to a controlled code transmitter 7, while the output of the switching circuit 4 is connected to the transmit antenna 5.

Fig. 2 is a more detailed view of the block diagram of Fig. 1, which illustrates a signal processing unit consisting of a controlled gate circuitry, a frequency synthesizer 3 and a switching circuitry 4 and their associated oscillator 1, which form the subject of the present invention. The output of the oscillator 1 is connected to one of the inputs of the first AND gate 2.1 of the controlled gate circuit 2 and the clock input of the counter 12 of the switching circuit 4. The random signal generator 10 is connected to the second input of the first AND gate 2.1 and to one of the non-OR gates 2.3 of the controlled gate circuit 2. The transmit start circuit 8 is connected to the second input of the aforementioned first non-OR gate 2.3 and to one of the inputs of a second AND gate 2.2. The first input of the same second AND gate 2.2 is also connected to the oscillator 1 as a clock generator. The first

2.1 Output of AND gate and second

2.2 The output of the AND gate is connected to a first input of the OR 2.4, the output of which is connected to one of the inputs 2.5 of the third AND gate 4 in the controlled gate circuit 2. The other input of this third AND gate 2.5 is connected via an inverter 2.6 to a transmission block 9. The output of the first non-OR gate 2.3 is connected to the RESET input of the counter 12 of the switching circuit 4, while the output of the third AND gate 2.5 is connected to a frequency synthesizer 3 having an output of three wires, one of which is it belongs to the logical level 1, the other is the frequency f ₂ , it belongs to the logical 0 level, and the third is the frequency f ₃ , which provides a signal proportional to the pause time. The frequency synthesizer output 3 of the frequency synthesizer ₃ is connected to one of the inputs of the fourth AND gate 4.3 in the switching circuit 4, the frequency output f is connected to one of the fifth AND gates 4.2 and the output of frequency f ₂ is the sixth AND gate 4.1. is connected to one of its inputs. The other input of the fourth AND gate 4.3 is connected via a second inverter 4.4 with an additional input of the fifth AND gate 4.2, an additional input of the sixth AND gate 4.1 and the output Q "of the counter 12. The third input of the fifth AND gate 4.2 is connected directly to the multiplexer output 11 of the sixth AND gate 4.1 via a third inverter 4.5. The fourth

4.3 The AND gate, the outputs of the fifth AND gate 4.2 and the sixth AND gate 4.1 are connected to the transmitter 5 via a second OR gate 4.6. The outputs of counter 12 with Q ₊ output are connected to multiplexer address selector input 11, while the same multiplexer 11 has a fixed but adjustable encoder output 6 and a controlled encoder output 7 connected to the data inputs.

Fig. 3 shows a variant of the transmitter in a manner known per se, comprising essentially a transistor amplifier and an associated oscillating circuit in the form of a magnetic dipole inserted into the collector circuit of the transistor, which is essentially a transmit antenna. Fig. 4 shows an exemplary receiver, the receiver antenna forming the receiver input, a loop located at the point of reception, coupled via a strainer 13 to a mixing stage 14 coupled to an oscillator 15, a center frequency filter 16, amplifier 18, via optional signal processing. A digital signal is already output at the output of the comparator 19.

The operation of the apparatus according to the invention is as follows. A fixed but adjustable encoder 6 connected to the input of the switching circuit 4 is a characteristic of a particular or monitored person or object, i.e. it produces an encoded signal for its identification. These 6 transmitters can be e.g. a dial that

-4197816 generates an appropriate sequence of digital signals for the data input of the 11 multiplexers. The random signal generator 10 generates the signal in a stochastic manner and transmits it to the input of the first AND gate 2.1 and the first NO gate 2.3 respectively. For example, the random signal generator 10 may be such that it provides an output signal for 20 msec, and then does not transmit for 1 second, which is repeated periodically. The break may be longer if necessary. The oscillator 1 continuously supplies the clock signal to the input of the first AND gate 2.1. When the signal of the oscillator 1 and the random signal generator 10 are in sync, the first AND gate 2.1 will be tipped over, i.e. it is at this time that the transmission takes place. Thus, practically any number of people can be observed within a given area, since the likelihood is generally very small that e.g. the random signal generator 10 and the oscillator 1 synchronize to more than one person or object simultaneously. The advantage of this solution is that the transmission time itself is extremely short, that is to say, despite the fact that the measurement is done by sampling, the total consumption of the equipment will be extremely small. A transmit start circuit 8 is connected to the other input of the controlled gate circuit 2, which operates by signaling the input of the second AND gate 2.2 and the input of the first NO gate 2.3. In this case, the receiver detects the person's signal as long as the start signal is present at the output of the transmit start circuit 8. The transmit start circuit 8 also provides, through suitable interfaces, the possibility of e.g. it may be possible to carry out speech transmission on the data transmission apparatus according to the invention. A.9 transmission enable blocking circuit is connected to the third input of the controlled gate circuit 2 and connected to the third AND gate 2.5 of the third via the first inverter 2.6. This produces a two-state signal sequence that, when one of its outputs has one state, the transmission is transmitted at the synchronization of the random signal generator 10 and the oscillator 1, but in its output a blocking signal is not transmitted. The transmit-blocking circuit 9 serves to prevent multiple transmissions. The function of the encoder, which is connected to the input of the switch circuit 4, is to detect various states or changes in the states. This can be accomplished, for example, by using either a digital output signal dial or another converter, e.g. operated by a microswitch line, and the output signal states depend on the position of the microswitches. In this way, the position, position and passing of different machines can be sensed.

The data transfer device according to the invention is very useful in difficult operating conditions, such as in mines such that information is not distorted, information can be reproduced, persons, machines or their various parameters can be continuously monitored and monitored so that virtually the their energy consumption is extremely low. The random signal generator 10 makes it possible to stochastically change the transmission density or the transmission periods of each transmitter. The transmission time is determined on the one hand by the number of persons or objects in the area to be monitored and, for example, by how long we want the equipment to operate, so energy consumption is another parameter to consider must be taken. The transmit start circuit 8 is e.g. it is capable of detecting passage of certain points along the conveyor belt. An advantage of the data transfer device according to the invention is that it can be used as a personal equipment item or as an interchangeable machine accessory, e.g. it can be mounted in the headlight of the miners or on its belt. It is also an advantage that continuous monitoring is carried out by sampling, so that multidirectional control and monitoring can be carried out simultaneously, and in places where uncertain detection situations may occur, the transmitter antenna is formed with a omnidirectional radiating antenna. The receiver antenna of the receiver is essentially an inductive loop on the ground, which can be arranged in several parts, so that the receiver loop can be formed of several loops, and thus it is actually possible to detect when moving forward e.g. a machine or a miner from one loop to another. This also allows the transmitter itself not to be overpowered, resulting in a further reduction in consumption.

The data transmission device according to the invention is therefore most advantageously used in hazardous workplaces, at workplaces where it is absolutely necessary, either for safety reasons or as a rule, to continuously monitor the situation of people in the area or the progress of machinery or fittings. The receiver is known per se and further processing of the signal from the receiver output can be carried out in an arbitrary manner, whereupon data can be stored and retrieved later, for example, who has been in a particular area and when.

Claims (6)

PATENT CLAIMS 1. Data transmitting equipment for determining the location of persons, objects, coding unit, signal processing unit connected to the output thereof and a transmitter having a known transmitter antenna connected to the output of the processing unit and a receiver antenna inductively connected to the transmitter, characterized in that in FIG The -5197816 signal processing unit comprises an oscillator (1) connected as a clock generator to a controlled gate circuit (2) and a switching circuit (4), the first input of the controlled gate circuit (2) being connected to a random signal generator (10) and a frequency generating a three-state FM code is connected via a synthesizer (3) to the first input of the switching circuit (4), which is the first input of a logic gate circuit having an additional input via an output counter (12) and an output of a multiplexer (11) interconnected, of which further elements of the switching circuit (4) are connected, and the multiplexer (11) address-indicating input is coupled to the outputs of the counter (12), while its data inputs are fixed with a code transducer (6) and a controlled code transmitter (7), and al The output of the gate circuit is connected to the transmitter (5), and the receiving antenna is a loop or loops formed of a wire laid in the space to be tested. The data transmission device according to claim 1, characterized in that the controlled gate circuit (2) is also provided with a second input to which an external transmit start circuit (8) is connected. The data transmission device according to claim 1 or 2, characterized in that the controlled gate circuit (2) is provided with an additional third input, to which a transmission blocking circuit (9) is connected. 4. A data transmission device according to any one of claims 1 to 4, characterized in 5 that the fixed but adjustable transducer (6) is equipped with a dial. 5. A data transmission device according to any one of claims 1 to 4, characterized in 10 that the controlled code transmitter (7) is a multi-digit transmitter coupled to a microswitch. The data transmission device according to claim 1, characterized in that the first and second inputs of the controlled gate circuit (2) 15 are interconnected to the oscillator (1), and the second input of the first AND gate (2.1) forms the first input of the controlled gate circuit (2) and a first non-OR gate is connected. 20 (2.3), while the same The other input of the non-OR gate (2.3) coupled to the other input of the second AND gate (2.2) forms the second input of the controlled gate circuit (2) and the first non-OR An output of 25 gate (2.3) is connected to the RESET input of counter (12) of the switching circuit (4), and the outputs of the first and second AND gates (2.1, 2.2) are connected to one of the inputs of the third AND gate (2.5). interleaved, the other input of which is the third input of the controlled gate circuit (2) via the first inverter (2.6), and the output of the third AND gate (2.5) forms the output of the controlled gate circuit (2).