DE10035295A1 - Dual communications system for dual communication and/or control-purposes e.g. for printers, TVs, and music equipment, involves waiting delay at transmission station over given time - Google Patents

Abstract

A communications method for data communication and/or control purposes between two separate transmission and reception stations, involves testing the signal communication from the transmitting station to the receiving station by IR-signal radiation, and testing the reception of the IR-signals at the reception station and with successful reception, sending a reception conformation signal as an IR-signal from the reception station to the transmission station. With non-reception of a reception signal, within a given time span, a renewed transmission test of the transmitting station by IR-radiation, is carried out. In the event of no radio check-back signal being received at the transmission station, a renewed transmission test is carried out by RF radiation with a given the amount of rise in the RF wave intensity.

Description

The invention relates to a dual system, namely an infra red / radio transmission system for data transmission and / or Control purposes.

The invention can be used, for example, for data transmission between spatially separated, wireless network components or terminals of a data processing company location, for example between a processor and a Printer, or between control or regulating devices and so wirelessly connected controlled components of control or Control loop forming systems, or for remote control of Telecommunication devices between remote control device and remote vision device, music system or the like

The goal is to enable a wiring-free connection networking of such devices in order to create a freer and to create more variable installation options and on the other hand to avoid cables hanging around or lying around.

A wireless connection has already been suggested or networking of components of data processing systems to manufacture via a radio system. It is with a fre frequency-modulated carrier signal in the shortwave range tet. The disadvantage here is that the radio waves at least  in the form of the carrier wave are always present, even if ge rade no data are being transmitted and that the radio waves fill the entire room and staff working in the room so constantly exposed to the exposure to radio waves is. This poses a significant health risk impairment, or at least the impairment the well-being of the staff due to constant stress with the radio waves.

On the other hand, remote control technology has long been an example as of television sets using infrared light signals between the remote control unit and the television set or one whose device the consumer electronics known. Their one however, it is known that possible uses are also possible subject to restrictions.

The invention is therefore based on the object, a lot System that can be used especially in rooms To provide data transmission and / or tax purposes, the reliable regardless of more or less favorable conditions wireless communication works and a as little biological impairment as possible People caused.

According to the invention, this object is achieved by a method or a device according to the independent claims solves. Advantageous embodiments of the invention are counter stood the subclaims.

Work with the method according to the invention or the one according to it The device according to the invention communicates between two devices or components on a dual basis an infrared or radio link.

This dual system is designed so that it is auto matically tries to initiate an infrared signal transmission For this purpose, the transmitter first sends signals in the form of Infrared signals. These signals from the receiving device  received correctly, this sends a feedback to the Em catching device also in the form of an infrared signal. The Transmitter is waiting for this feedback, and should be are not received by the transmitter, the transmitter evaluates the lack of feedback as an indication that a correct infrared transmission to the receiving device is not possible and automatically switches to radio operation Performance around. It then sends the same information more in the form of radio signals of low intensity Receiving device which, when it receives the signals, in turn a feedback to the sending device, which, if the Information received via radio is also received automatically done via radio. If the transmitter still does not have one Acknowledgment received from the receiving device is done by the sender advises a new attempt to send again in the form of radio signals, but with increased intensity. This procedure can be done with a series of graduated radio intensities are repeated, until the connection between the two devices works. Of course, all of this takes place in a very short time.

In this way it is possible to be in a wireless network Arrangement of a plurality of devices, each as a transmission or receiving device can function at different stands locations in a building on the same floor or in can be on different floors and via infrared or radio connection different well relative to each other are accessible so that the devices are each dependent on the quality of the connection to the other device automatically between infrared and radio signals more or less intense intensity the possible ver connection path with the lowest possible radio wave load chooses. The biological burden on people is thereby kept to the minimum possible.

The invention is illustrated below by means of an embodiment game with reference to the attached schematic Drawing described in more detail in the form of a Block diagram of a dual communication system according to the invention  shows.

The drawing shows two devices 1 and 2 communicating with one another. To simplify matters, device 1 is shown as a transmitting device and device 2 as a receiving device (in relation to the information or data transmission to be carried out). In a practical system, this can also be the case if a transmission of information or control data or the like is to be carried out only in one direction, but it is understood that, depending on the application, both devices also function both as a transmitting device and as a receiving device can kick. It is further understood that a practical system needs to include not only two devices, as shown in the schematic drawing, but an arbitrarily networked arrangement of several devices, some or all of which are transmitters and some or all of which are receivers or both can be operated as a transmitting and receiving device.

The transmitting device 1 itself generates or receives information, data or commands to be transmitted at an input 10 . The receiving device 2 processes the information, data or commands itself or outputs them at an output 20 .

A first block 11 in the transmitter 1 can be used to process the input signal at input 10 , for example in the form of an analog-digital conversion, coding or the like, if this is necessary. The next block 12 of the transmitter is a switch in which the signal to be transmitted is forwarded into an infrared transmitter circuit (switch position shown) or into a radio transmitter circuit (other switch position). In the switch position shown, the possibly processed signal thus arrives in a block 13 , which embodies the infrared transmission circuit and, if necessary, amplifies and converts the signal accordingly, before it reaches an infrared lamp as shown and is emitted there.

If the changeover switch 12 is in the other switch position, the possibly processed signal passes into a block 14 which represents a first part of the radio transmission circuit and serves for the corresponding conversion of the signal to be transmitted into a frequency-modulated carrier signal. This is followed by a further block 15, an amplifier circuit, which forms a second part of the radio transmission circuit and serves to amplify the signal to the required transmission power. The amplifier is, as shown, variable and can change the transmission power, that is to say the intensity of the radio signal directed and emitted from there to a transmission antenna, in steps or continuously.

Both the changeover switch 12 and the gain controller of the amplifier 15 are controlled or actuated by a control unit shown as block 16 . The control unit 16 receives an input signal from the block 11 , which receives the signal arriving at the input 10 of the transmission circuit 1 and receives the given signal and, if necessary, processes it and initiates the transmission process, so that the control unit 16 knows when a transmission process is to be carried out. The control unit 16 also receives input signals from blocks 17 and 18 . Block 17 embodies an infrared receiver circuit and block 18 a radio receiver circuit. Both serve to receive and decode feedback signals from the receiving circuit 2 .

If an infrared signal is emitted by the transmitter circuit 1 via the infrared transmitter circuit 13 and the infrared lamp, this infrared transmitter signal should be received and decoded by the receiver circuit 2 via a receiver, shown schematically as a lens, and an infrared receiver circuit 21 . If this is the case, the infrared receiving circuit 21 not only forwards the decoded received signal to the output 20 , but also transmits corresponding reception information to a block 22 forming a control unit, which in turn causes an infrared transmitter circuit 23 to emit a confirmation signal via an infrared lamp , which is again received schematically as a lens receiver and the infrared receiver circuit 17 of the transmitter 1 is received. This infrared receiver circuit 17 then transmits a corresponding receipt confirmation to the control unit 16 , which he knows from the fact that the transmission process over the infrared transmission path is or was successfully carried out.

If the signal transmission via the infrared transmitter does not work or does not work sufficiently, there is no corresponding feedback from the receiver 2 and the infrared receiver circuit 17 in the transmitter 1 does not receive a corresponding acknowledgment of receipt and does not forward such to the control unit 16 . If the control unit 16 does not receive a confirmation signal within a certain period of time, the control unit 16 interprets this in that the infrared transmission path does not work and a successful signal transmission is not possible in this way. The control unit 16 therefore switches the changeover switch 12 to its other position, so that the signal from the block 11 is now forwarded to the radio transmission circuit 14 , 15 and processed and amplified for the purpose of radio transmission. The gain controller of amplifier 15 is at the lowest gain level.

The transmitter circuit 1 thus makes a failed attempt to transmit the signal via the infrared transmission link, the attempt to transmit the signal as a radio signal of low intensity via the radio transmission antenna. If this succeeds, the receiving device 2 receives the radio signal via the receiving antenna and the radio receiving circuit 24 , which decodes the signal accordingly. The radio reception circuit 24 then in turn conducts the decoded reception signal to the output 20 and, in addition, outputs a signal that signals the radio reception to the control unit 22 , which then activates a radio transmission circuit 25 to receive an acknowledgment signal via the radio link to the radio antenna and the radio reception circuit 18 of the transmission device 1 to transmit. Upon receipt of such an acknowledgment signal via the radio link from the receiving device 2 , the radio receiving circuit 18 passes a corresponding receiving confirmation signal to the control unit 16 of the Sendege device 1 , which recognizes that the signal transmission over the radio link works with low intensity.

However, if this does not succeed either, ie the radio receiver circuit 18 does not receive a corresponding feedback signal and the control unit 16 does not receive a corresponding reception confirmation, the control unit 16 interprets this as a non-functioning radio link with low radio power and therefore actuates the amplification controller of the amplifier 15 in order to increase the radio signal intensity by one level. Even if there is still no functioning radio transmission, the control unit 16 increases the radio signal intensity by a further stage by actuating the gain controller of the amplifier 15 , and this process is repeated, if necessary, until the highest radio power level is reached.

In this way, signal transmission is always first tried the path of infrared transmission and only if that not working, is switched to radio operation and thereby worked with the lowest possible transmission power.

Without being shown in the schematic drawing, the system can be further developed in such a way that the control unit 16 initially maintains a determined necessary setting for radio operation with the determined necessary amplification stage over a certain period of time, that is to say also for subsequent transmission processes, so that a plurality of transmission attempts is not started with each transmission process. The arrangement can be made so that after a certain period of time, the control unit in the next transmission process only tries to switch down to the next lower radio intensity level in order to finally return to the lowest radio intensity level or to infrared transmission. This allows for the fact that changing conditions in a given room can be taken into account. It goes without saying that all of the processes described naturally take place extremely quickly.

The drawing with the functional blocks shown and their order only serves to explain the way of working of the invention and is for practical embodiments of the Invention not binding.

Claims (6)

1. Communication method for data transmission and / or control purposes between two spatially separate transmitting and receiving stations, with the following steps:

• a) attempting to transmit signals from the transmitting station to the receiving station by emitting infrared signals,
• b) attempt to receive the infrared signals at the receiving station, and if reception is successful, sending a reception confirmation signal also as an infrared signal from the receiving station to the transmitting station,
• c) Waiting at the transmitting station over a certain period of time whether a reception confirmation signal is received by the receiving station,
• d) If an acknowledgment signal is not received within the given time period, a new transmission attempt is carried out from the transmitting station by radio radiation with low radio signal intensity instead of by infrared radiation,
• e) in the event of successful reception at the receiving station, sending a radio feedback signal from the receiving station to the transmitting station,
• f) waiting at the transmitting station over a given period of time whether a radio feedback terminal is received by the receiving station,
• g) If no radio feedback signal is received at the transmitting station during the given period of time, retry the transmission by radio radiation with radio wave intensity increased to a certain extent,
• h) repeating steps e), f), and optionally g) until a radio feedback signal confirming successful transmission is received by the receiving station at the transmitting station.

2. Dual communication system for data transmission and / or control purposes between two spatially separated stations ( 1 , 2 ), with the following features:

• a) The transmitting station (1) has both an infrared transmitting TIC (13) and a radio transmitting circuit (14, 15) and the receiving station (2) comprises an infrared receiving circuit (21) and a radio receiving circuit (24),
• b) the receiving circuit ( 2 ) has a feedback signal infrared transmission circuit ( 23 ) and a feedback signal radio transmission circuit ( 25 ) and the transmitting station ( 1 ) has a feedback signal infrared reception circuit ( 17 ) and a feedback signal radio reception circuit ( 18 ),
• c) The transmitting station ( 1 ) has a changeover switch ( 12 ) for optionally switching the signal to be transmitted to the infrared transmitting circuit ( 13 ) or the radio transmitting circuit ( 14 , 15 ), which can be actuated by a control unit ( 16 ),
• d) The radio transmission circuit ( 14 , 15 ) has a signal level adjuster ( 15 ) with a plurality of selectively adjustable signal intensities, which can be operated by the control unit ( 16 ),
• e) The receiving station ( 2 ) contains a control unit ( 22 ) which, when an infrared signal is received by the infrared receiving circuit ( 21 ), the feedback signal infrared transmission circuit 23 and when a radio signal is received by the radio receiving circuit ( 24 ), the feedback signal radio transmission circuit ( 25 ) activated
• f) The control unit ( 16 ) first switches the switch ( 12 ) to the infrared transmitter circuit ( 13 ) and only switches it to the radio transmitter circuit ( 14 , 15 ) if not within a certain period of time after a transmission process a feedback signal from the infrared receiver circuit ( 17 ) was received,
• g) The control unit ( 16 ) keeps the signal level adjuster ( 15 ) at the lowest intensity setting and actuates the signal level adjuster only in the sense of increasing the signal intensity by a certain amount if the changeover switch ( 12 ) switches to the radio transmission circuit ( 14 , 15 ). is changed over and within a certain period of time after a transmission process no feedback signal from the radio receiving circuit ( 18 ) was received.

3. System according to claim 2, wherein the control unit ( 16 ) is designed so that it maintains this setting even after the completion of a transmission process after switching over the switch ( 12 ) to the radio transmission circuit ( 14 , 15 ) for a fixed or selectable period , 4. System according to claim 2 or 3, wherein the control unit ( 16 ) keeps the setting of the signal level adjuster ( 15 ) after this has been adjusted to a higher intensity, even after the completion of a transmission process over a fixed or selectable period in this setting. 5. System according to claim 4, wherein the control unit ( 16 ) after the expiry of said period or already during the said period during the next transmission process, the signal level adjuster ( 15 ) initially lowers an intensity level. 6. System according to claim 3, wherein the control unit ( 16 ) only when the signal level control ( 15 ) is in the lowest intensity setting, after the expiry of said period or already during said period during the next transmission process, the switch ( 12 ) on Infrared transmission circuit ( 13 ) switches back.