DE102004062729A1 - Method and circuit arrangement for data transmission by means of infrared remote control - Google Patents

Abstract

A method and a circuit arrangement for data transmission by means of infrared remote control are to be created, which have a low power consumption. Furthermore, the time delay between the operation of the transmitter and the response of the device should be kept very small and it should be possible to fine tune. DOLLAR A According to the invention, the problem is solved in terms of the process that by a transmitter (12) after its activation, the transmission of the data. Each data telegram is composed of a data part (38) and a synchronous gap (39). Furthermore, an infrared receiving module (23) is turned on. In this case, the time interval between the activation of the infrared receiving module (23) is asynchronous to the time interval of the transmission of the data telegram transmitted by the transmitter (12). Furthermore, the duration of the switch-on (40) is significantly smaller than the duration of the pause (41) between two switches (40). When Wahnehmung of at least one bit of the data telegram by the infrared receiving module (23), the duration of the activation (40) is increased so that it is greater than the time interval of the transmission of the data telegrams. DOLLAR A The method and the circuit arrangement for data transmission by means of infrared remote control can be used in gas control valves.

Description

technical area

The The invention relates to a method for data transmission by means of infrared remote control and a circuit arrangement for carrying out this method, such as They use a variety of types of remote control operable electrical appliances can be used.

options for data transmission by means of infrared remote control comes in a variety of designs. Usually these exist Remote controls from a remote control and a remotely controllable Device assigned Receiver. The for The receptivity of the recipient energy required is in the general over the electrical appliance connected to the electrical network, because the power consumption of the receiver known remote controls for the willingness to receive in terms of capacity of usually in This range of batteries used is relatively high, so that the desired life is not achieved.

In order to achieve a satisfactory lifetime even when using batteries, is in the EP 0 663 733 A1 a remote control for an electrically operated, remotely controllable device described. Here, the receiver is connected via an interval switch to a battery-powered circuit for power supply and is cyclically supplied with electrical energy.

Additionally points the transmitter has a circuit for a start signal whose transmission time is the period of the switching intervals exceeds the interval switch, so that too during the intermittent reception readiness of the receiver, the start signal can be received. Due to this start signal, the interval switch becomes controlled and the receiver at least for the transmission time of the subsequent to the start signal control signal transmission Continuously connected to the power supply.

These execution is very expensive, because for the Providing the start signal requires additional circuitry is. Furthermore, a correspondingly long response time until actual control of the device needed. It is therefore not suitable for the control of devices, For example, electric motors with which causes a fine adjustment shall be.

From the DE 196 26 950 A1 A device for reducing the standby power of an electrical device is known. This device is intended for devices which are to be completely disconnected from the power supply in standby mode and during which time the operation should be as low in power as possible. For this purpose, the device has a receiver circuit with at least one photodiode for receiving the pulsed light signals transmitted by the remote control, a resistance circuit connected in parallel with the photodiode for compensating for unparalleled light signals and a mains connection for a supply voltage.

Next the fact that this device is only for the temporary separation of Power supply is suitable, it has a complex and complicated Circuitry on. Furthermore This device is also due to the necessary switching from standby - up Power grid operation existing turn-on delay not suitable for the purpose where a remote-controlled fine adjustment is required or required becomes.

Furthermore, in the DE 100 54 529 A1 describes an energy-saving method for the wireless reception of data modulated on a carrier signal. In this method, based on the already above under EP 0 663 733 A1 described solution of the receiver circuit is not fully enabled in the intermittent operation of the operating voltage source, but the required for recovering the data from the modulated carrier signal circuit parts are continuously supplied with electrical energy. In contrast, the other circuit parts are intermittently supplied with electrical energy.

Next the heightened technical effort and the higher Energy requirements are the disadvantages already mentioned also in this execution not eliminated.

To a completely different type of execution is in the DE 43 09 006 A1 said device for wireless data transmission. In this device, which has at least one transmitter and a receiver which is tuned to the transmitter, the energy is supplied by means of solar cells.

Here It is disadvantageous that in addition to the required effort too the corresponding spatial, in particular the lighting conditions must be given to a proper function to ensure.

presentation the invention

The invention is based on the problem a method for data transmission by means of infrared remote control and to develop a circuit arrangement for carrying out this method, which have such a low power consumption that while ensuring a sufficient life and integrable voltage sources for receivers and transmitters can be used, the only a small power consumption or As batteries have only a small capacity. Furthermore, the time delay between the operation of the transmitter and the response of the device should be kept very small, above all, a fine adjustment should be possible. The structure is as simple and inexpensive to design.

According to the invention Problem procedurally solved that by a transmitter after its activation the immediate periodic transmission of the data takes place in the form of serial data telegrams. Everybody is here Data telegram from a data part, consisting of individual bits, which in turn are clocked, and composed of a synchronous gap, wherein the duration of the data portion and the duration of the synchronous gap are similarly long are fixed. Furthermore, an infrared receiving module of a receiver switched on intermittently. Here is the temporal Distance between the pulse-like activation of the infrared receiver module asynchronous to the time interval of the transmission of the transmitter emitted serial data telegrams. Furthermore, the duration of the activation of the infrared receiving module is significantly smaller than the duration of the Pause between two starts. In the perception of at least one bit of the data telegram through the infrared receiving module of the recipient the duration of the activation of the infrared receiver module automatically so magnified that she is taller than the time interval of the transmission of the data telegrams is, thereby the following data telegram is completely received and evaluated can be.

In order to became a solution found, with the above-mentioned disadvantages of the prior Technique were eliminated.

By Immediate transmission of the data telegrams and under consideration a corresponding clock frequency of the receiver, it is possible the response time until the actual activation of the device so far to reduce that it is practically unnoticeable during use. Furthermore can also be controlled by this method, an electric motor, as he or the like for fine adjustment, for example, the opening stroke of valves. is used. This results from the only impulsive operation of the Infrared receiver a very low power requirement, so too for the receiver can be resorted to integrable voltage sources.

advantageous Embodiments of the invention will become apparent from the other claims.

So proves to be especially for one possible small response time as low, if that is from the time interval of the pulse-like activation of the infrared receiving module resulting clock frequency and out the time interval of the transmission of the data telegrams resulting Refresh rate only slightly differ.

A more cheap Embodiment for achieving a small response time is therein to see that the duration of the pulse-like activation of the Infrared Receive Module is set to be larger than the longest Duration of a gap is in the clocked data part.

In dependence whether the energy savings at the receiver or at the transmitter are higher should, on the one hand, it is possible that the clock frequency of the receiver is smaller than the repetition frequency of the transmitter, while on the other hand the Clock frequency of the receiver is larger as the repeater frequency.

to increase the safety of the method is particularly evident for the application for safety-related devices, like control or regulating devices in gas technology, an advantageous embodiment of the method, if further processing of the transmitted data only then takes place if at least two subsequent data telegrams are identical are. This prevents the occurrence of incorrect transmissions.

by the circuit arrangement is the problem according to the invention in the claims 7 or 8 specified characteristics solved.

For a more detailed explanation of the method according to the invention and the circuit arrangement according to the invention for data transmission by means of infrared remote control, a gas control valve, as used in the following example, serves as an example DE 103 05 929 B3 is explained in more detail. The individual representations show:

1 a schematic representation of the method using the method using gas control valve,

2 a detailed representation of a circuit arrangement according to the invention,

3 a schematic representation of the temporal pulse-like activation of the infrared receiver module in standby mode,

4 a schematic representation of the temporal periodic transmission of data by the transmitter,

5 a representation of another arrangement according to the invention.

In the 1 illustrated gas control valve is designed as a switching and control device preferably for installation in a gas-fired stove or the like. It enables the operation and monitoring of a burner by controlling the amount of gas flowing to the burner. The burner consists in this embodiment of a pilot burner 25 and a main burner 26 ,

In the case of a location-independent remote control 6 is the transmitter 12 who works with a recipient who is tailored to him 14 forms an infrared remote control.

To control the functional elements of the gas control valve is an electronic control unit 5 , which in this embodiment together with a voltage source 44 and the receiver 14 The infrared remote control is housed in a separate housing. The control unit 5 is connected via an electrical line to the gas control valve. As infrared receiver module 23 a commercially available type is used, which is characterized in that it has no or no noticeable transient response. The possible consumption is at a voltage of 4 to 6 V at about 1.2 to 1.5 mA. To the reception characteristics of the receiver 14 To make cheaper, serving as a sensor infrared receiving module 23 mounted separately outside the stove, so that it is in the field of view of the transmitter 12 located. It is then of course via an electrical line to the receiver 14 connected.

In 2 is the circuit of the used receiver 14 shown in detail.

The one with a voltage source 44 , which provides a voltage of 6 V in this embodiment, connected infrared receiving module 23 is an oscillator 33 upstream. In this case, the diode D1 in conjunction with the resistor R2 connected in series are used for timing the pulse-like activation 40 and the two series-connected resistors R1 and R3 for setting the pause 41 , On two resistors to adjust the break 41 is therefore used, because a finer adjustment of the time interval of the pulse-like switching 40 of the infrared receiver module 23 at the time interval of the transmission of the transmitter 12 transmitted serial data telegrams is enabled.

Like from the 3 can be seen, the oscillator points 33 an extreme ratio between the duration of the pulse-like engagement 40 , in this case 1 ms, and the time duration between two starts 40 lying break 41 , in this case 45 ms, in standby mode. As a result, the energy consumption is kept very low.

Between the oscillator 33 and the infrared receiving module 23 There are a CMOS circuit S3 acting as an inverter, and a transistor T1, which is the switch function for the pulse - like activation 40 of the infrared receiver module 23 takes over. The infrared receiver module 23 is a downstream acting as a NOR gate CMOS circuit S4, which is that of the infrared receiving module 23 received data parts to the data output 42 forwarded and at the same time serves via a diode D2 for charging a storage capacitor C3. The storage capacitor C3 is followed by a transistor T2. The second input of the CMOS circuit S4 is via a differentiator 34 connected to the output of the CMOS circuit S3. The differentiator 34 serves to hide the by the pulse-like activation 40 caused on-off signal on the receive data line 35 ,

Around the structure as possible easy and inexpensive to shape, conveniently all four CMOS circuits S1 to S4 in FIG a CMOS circuit integrated, which is supplied with a voltage of 3V.

• • Inbetriebnahme 7 mit Zündsicherung
• • Steuerungseinheit 8 für die zum Hauptbrenner 26 strömende Gasmenge

The gas control fitting consists of a housing 1 that has a gas inlet 2 , a Zündgasausgang 3 and a main gas outlet 4 having. In the case 1 the following functional units are accommodated:

• • Installation 7 with ignition protection
• • Control unit 8th for the main burner 26 flowing gas

For commissioning 7 is in a storage place 9 of the housing 1 an actuating rod 10 longitudinally movably guided, which over one on the housing 1 arranged electromagnet 11 by means of the remote control 6 is operable.

The movement in the longitudinal direction is only against the force of a in the housing 1 supporting return spring 13 possible. The operating rod 10 reaches with its end into the interior of the case 1 ,

The interior of the housing 1 is through a partition 15 divided into different rooms. Escaping in extension of the operating rod 10 has the partition 15 a first opening 16 on that to an ignition safety valve 17 belongs. The ignition safety valve 17 is by one in a storage location of the housing 1 gas-tight arranged thermoelectric Zündsicherungsmagneten 18 influenced, the downstream of the gas inlet 2 located. The thermoelectric ignition safety magnet 18 acts on an anchor 19 that is rigid with a valve stem 20 is connected, on which the valve disk 21 of the ignition safety valve 17 is attached. About the electronic control unit 5 , as well as over a pilot flame exposed thermocouple 22 is the thermoelectric ignition safety magnet 18 excitable.

The structure and operation of the Zündsicherungsmagneten 18 Incidentally, the person skilled in the art are familiar, so that the description of further details can be dispensed with.

In flow direction behind commissioning 7 is inside the case 1 a to the control unit 8th belonging switch 24 which is designed to be a modulating control via a valve 32 with jump-like switching on and off in the partial load range via a valve 29 is effected. In this case, the partial load flow through the cross section of an opening 27 limited.

One with the switch 24 in frictionally connected and longitudinally movable plunger 28 stands out from the same time a depository 30 for him forming housing 1 out. With his the switch 24 opposite end is the plunger 28 with a drive unit 31 connected here, which consists of an electric motor, over which, driven by the electronic control unit 5 , the position of the plunger 28 is changeable.

The procedure of the procedure is as follows: Via the remote control 6 For example, if a command is given to ignite the gas control valve or, for example, to increase the gas flow when the ignition flame is already burning, the transmitter immediately becomes 12 and starts sending the corresponding serial coded data telegram. This data telegram consists of individual bits, which in turn are clocked. The transmission of the data telegram is repeated at a fixed repetition frequency. Here is the duration of the data part 38 similar to the duration of the synchronous gap 39 selected. In this example, the duration of the data part is 38 a serial data telegram, as shown 4 16 ms and the duration of one data telegram plus a synchronous gap is defined as 32 ms.

The infrared receiver module 23 will be in standby mode via the oscillator 33 turned on impulsively. During the pulse-like intervention 40 the input of infrared signals is checked. Every 45 ms, the infrared receiver module will be activated 23 switched on for the duration of 1 ms ( 3 ). Through the differentiator 34 In this case, in combination with the CMOS circuit S4 operating as a NOR gate, the signals produced by the oscillator 33 taking pulse-like activation 40 resulting inrush on the receive data line 35 hidden.

After a waiting time W, at least one bit of a data telegram encounters an activation 40 and the storage capacitor C3 is charged via the diode D2. As from the synopsis of 3 and 4 can be seen, this is due to random waiting time W in the range of 0 to a few milliseconds, ie not visible in practical operation. Conveniently, this is the duration of the pulse-like activation 40 of the infrared receiver module 23 set to be greater than the longest duration of a gap 43 in the clocked data part 38 is.

Via the transistor T2, the oscillator 33 disabled by shorting its output and the infrared receiving module 23 is turned on by the storage capacitor C3 for a period longer than the time period of one data telegram, that is, one data part 38 plus a synchronous gap 39 is. This ensures that the next consecutive data telegram is received and evaluated with all its information. As long as more data parts 38 arrive the control remains.

To now, as desired with gas appliances, a high level of security against the disclosure of any erroneously received or interpreted data parts 38 to reach, conveniently takes place in the electronic control unit 5 Further processing of the transmitted data only if at least two subsequent data telegrams are identical.

But even in this case, the drive of the drive unit 31 so fast and so finely possible that over the drive unit in this embodiment 31 forming electric motor, for example, the desired setting of the valve 29 to control the main burner 26 is ensured flowing gas.

Be by the transmitter 12 no data telegrams sent, so the storage capacitor C3 is no longer charged and the output of the oscillator 33 no longer shorted. The recipient 14 goes back to the initially described standby mode.

In 5 is a slightly different experience Arrangement according to the invention shown schematically, which is particularly characterized by its simplicity. In this arrangement, there is a programmable microcontroller 37 , Of course, with low power consumption, use. This microcontroller 37 is over an exit port 46 and an input port 45 with the infrared receiver module 23 connected. The connection of the other available output or input ports of the microcontroller 37 are not considered in detail in this example, since they are not essential to the invention. The starting port 46 serves to output the activation 40 via the transistor T1 and a switch-on line 36 from the microcontroller 37 to the infrared receiver module 23 and the input port 45 for entering the data telegrams via a receive data line 35 to the microcontroller 37 ,

The inventive method and the circuit arrangement for carrying out this method are of course not limited to the illustrated embodiment example. Rather, changes, modifications and combinations are possible without departing from the scope of the invention. So it is understood that, for example, the times indicated in this embodiment for the period between two pulse-like Einschaltungen 40 and the length of the same can be varied. This of course also applies to the specified values of the data telegram.

1

casing

2

gas input

3

ignition gas output

4

Main gas output

5

control unit

6

remote control

7

Installation

8th

control unit

9

depository

10

actuating rod

11

electromagnet

12

transmitter

13

return spring

14

receiver

15

partition wall

16

opening

17

ignition locking

18

ignition locking

19

anchor

20

valve rod

21

valve disc

22

thermocouple

23

Infrared receiver module

24

switch

25

pilot burner

26

main burner

27

opening

28

tappet

29

Valve

30

depository

31

drive unit

32

Valve

33

oscillator

34

Differentiator

35

Receive data line

36

turn-on

37

microcontroller

38

data part

39

synchronous gap

40

intervention

41

Break

42

data output

43

gap

44

voltage source

45

input port

46

output port

C3

storage capacitor

D1

diode

D2

diode

R1

resistance

R2

resistance

R3

resistance

S1

CMOS circuit

S2

CMOS circuit

S3

CMOS circuit

S4

CMOS circuit

T1

transistor

T2

transistor

Claims (8)

Method for transmitting data by means of infrared remote control, in which • by a transmitter ( 12 ) after its activation the immediate periodic transmission of the data takes place in the form of serial data telegrams, - the one data part ( 38 ), consisting of individual bits, which in turn are clocked and - the one synchronous gap ( 39 ), the duration of the data part ( 38 ) and the duration of the synchronous gap ( 39 ), • an infrared receiver module ( 23 ) of a recipient ( 14 ) is intermittently switched on, wherein - the time interval of the pulse-like activation ( 40 ) of the infrared receiving module ( 23 ) asynchronously to the time interval of the transmission from the transmitter ( 12 ) is serial data telegram sent, - the duration of the activation ( 40 ) of the infrared receiving module ( 23 ) is significantly smaller than the time between the two starts ( 40 ) break ( 41 ) is, when perceived by at least one bit of the data part ( 38 ) through the infrared receiving module ( 23 ) Recipient ( 14 ) the duration of the activation ( 40 ) of the infrared receiving module ( 23 ) so enlarged is that it is greater than the time interval of the transmission of the data telegrams. Method for transmitting data by means of infrared remote control according to Patent Claim 1, characterized in that the time interval of the pulse-like activation ( 40 ) of the infrared receiving module ( 23 ) resulting clock frequency and the resulting from the time interval of the transmission of the data telegram repetition frequency of the transmitter ( 12 ) differ only slightly. Method for data transmission by means of infrared remote control according to claim 1 or 2, characterized in that the longest duration of a gap ( 43 ) in the clocked data part is set to be smaller than the duration of the pulse-like activation ( 40 ) of the infrared receiving module ( 23 ) Method for data transmission by means of infrared remote control according to one of the claims 1 to 3, characterized in that the clock frequency of the receiver ( 14 ) is smaller than the repeater frequency ( 12 ). Method for data transmission by means of infrared remote control according to one of the claims 1 to 3, characterized in that the clock frequency of the receiver ( 14 ) is greater than the repeater frequency ( 12 ). Method for data transmission by means of infrared remote control according to one or more of the claims 1 to 5, characterized in that a further processing of the transmitted Data only takes place if at least two subsequent data telegrams are identical. Circuit arrangement for carrying out the method for data transmission by means of infrared remote control with • one with a voltage source ( 44 ) connected infrared receiver module ( 23 ), • an infrared receiver module ( 23 ) upstream oscillator ( 33 ) for pulse-like activation ( 40 ) of the infrared receiving module ( 23 ), • an infrared receiver module ( 23 ) downstream CMOS circuit (S4) acting as a NOR gate, on the one hand a data output ( 42 ) And on the other hand a storage capacitor (C3) which can be charged via a diode (D2) and a transistor (T2) are arranged downstream, the second input of the CMOS circuit (S4) being connected via a differentiating element (C4) 34 ) is connected to the output of the CMOS circuit (S3). Arrangement for carrying out the method for transmitting data by means of infrared remote control with a voltage source ( 44 ) connected infrared receiver module ( 23 ), • a programmable microcontroller ( 37 ), which has an output port ( 46 ) and an input port ( 45 ) with the infrared receiver module ( 23 ), wherein • the output port ( 46 ) for issuing the pulse-like activation ( 40 ) of the infrared receiving module ( 23 ) via a switch-on line ( 36 ) from the microcontroller ( 37 ) to the infrared receiver module ( 23 ), • the input port ( 45 ) for entering the data parts ( 38 ) via a receive data line ( 35 ) to the microcontroller ( 37 ) serves.