DE2110795A1 - Device for transmitting signals of different bandwidths over a common transmission path - Google Patents

Description

Performing the transmission of signals of different types Bandwidth over a common transmission path

The invention relates to a device for transmitting signals of different bandwidths, in particular from Speech and measured value signals, in which the individual signals are scanned at a time via a common Transmission path transmitted to a receiving device and separated there again by appropriate scanning.

In known devices of this type, the signals to be transmitted, for example telephone calls or the like, essentially all have the same bandwidth. All signal channels and thus equally in terms of their transmission quality and also equally utilized. However, if one were to use such a transmission channel designed for a broadband signal, narrowband signals, 7, Ai. Measured values that change slowly over time are transmitted, the relevant channel would not be full

209838/0987

2110793

exploited. This means an excess in the channel capacity, which would not, or only to a minor extent, result in an improvement in the transmission.

The object of the invention is to provide a device of the type mentioned at the outset which, with full exhaustion of the channel capacity a secure transmission of both broadband and narrowband signals is guaranteed.

The object is achieved according to the invention in that the sampling frequency for the signals with a larger bandwidth this is selected correspondingly higher than for signals with a smaller bandwidth .

The device according to the invention allows optimal utilization of the channel capacity. Should, for example, have a Transmission channel a total of one voice signal and five measured value signals are transmitted, the total sampling frequency results E.g. to 16 kHz if the standard value of 8 kHz is used as the sampling frequency for the voice signal and a sampling frequency is used for each measured value 8 kHz: 5 = 1.6 kHz is selected. A sampling frequency of 1.6 kHz means that the measured value signals have a bandwidth of approx. 800 Hz, which is fully sufficient for a perfect transmission of these signals (e.g. EKG, breathing signal, etc.) is. For the transmission of a total of one voice signal and five measured value signals, compared to the voice signal only requires twice the bandwidth. If the five measured value signals were conventionally connected to the full voice bandwidth are transmitted, so the Gestimtabtastfrequena and thus also the. Total bandwidth of the transmission path to six times the value of the sampling frequency or the bandwidth of the individual speech signals has been increased.

209838/0987

In an advantageous embodiment of the invention, the sampling frequency should for each signal correspond to at least twice the value of the bandwidth of this signal. With devices According to the invention, in which the duration of a sampling is determined by the duration of a sampling pulse, it is expedient to the sampling of the signal with the greatest bandwidth, e.g. speech signal, using a sampling pulse sequence with the sampling. ratio 1: 1 to perform and the sampling pulses for the signals with a lower bandwidth after 'a preferably regular Scheme of the individual pulse pauses in this sampling _ " to distribute pulse train.

Further advantages of the invention are based on the drawing, which shows an embodiment of the invention, in explained in more detail below.

In FIG. 1, which shows the basic circuit diagram of the device according to the invention, 1 denotes an input channel for a broadband signal, for example a voice signal (approx. 4 kHz). The input channels 2 and 3 are intended for narrowband signals, eg measured value signals (maximum 800 Hz). The individual input channels 1,2 and 3 are switches 4, 5 and 6 alternating λ, to a high frequency transmitter 7 connectable. The switches 4, 5, 6 are switched on at the rate of clock pulse sequences of different pulse repetition frequencies generated at the outputs 8, 9, 10 of a clock pulse generator 11.

The signals reaching the high-frequency transmitter 7 are modulated in the transmitter and emitted via a transmitting antenna 12. To The modulated ones are passed through the transmission path 13 Signals from a receiving antenna 14 are picked up again and fed to a receiving amplifier 15. At the output of the receiving amplifier 15 there are a total of three capture channels 16, 17, 18, the channel 16 being the receiving channel for the broadband

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Signal forms and the channels 17 and 18 for the narrowband Signals are provided. Correct routing of the received signals to the associated receiving channels 16 to 18 (selection of the signals) is done using switches 19, 20 and 21, which are synchronized with switches 4, 5 and 6 on the transmitter side Connect the individual channels 16 to 18 to the receiving amplifier 15. The respective switching cycle of switches 19 to 21 is synchronized by a clock generator 1-1 on the transmitter side (via synchronization pulses) clock generator 22 on the receiving side is supplied.

The circuit elements 23 to 25 provide filters for the demodulation of the individual signals.

Fig. 2 shows a pulse diagram of a total of five clock pulse trains, as generated, for example, by the clock generator 11 of FIG. The pulse scheme of FIG. 2 can, for example for the transmission of a voice signal as well as overall five measured value signals can be used. The pulse sequence IL (t) then controls, for example, the switch 4 according to FIG. 1, the pulse train up (t) the 'switch 5' the pulse train U, (t) den Switch 6 and the pulse trains U, (t), U, - (t) and Ug (t) others switch not shown in FIG.

If the value 4 kHz is selected as the maximum bandwidth to be transmitted for the voice signal, the pulse repetition frequency of the pulse train U .. (t) is 8 kHz with a duty cycle of 1: 1. If the bandwidth of the measured value signals to be transmitted is 800 Hz in each case, the pulse repetition frequency of the pulse trains U ₂ (t) to Ug (t) is 1.6 kHz. The total sampling frequency is thus 16 kHz. The individual sampling pulses of the pulse trains U ₂ (t) to Ug (t) are based on a regular pattern on the one-pulse pauses of the pulse

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follow U ₁ (t) distributed. According to Pig. '2 is the first pulse of the pulse train U _? (t) placed in the first pulse pause of the pulse train U ₁ Ct). The first pulses of the next following pulse trains U -, (t) to Ug (t) are then placed in the next following still free pulse pauses of the pulse train U ₁ Ct).

3 shows a further pulse diagram for the control of the switches 4, 5 and 6 according to another exemplary embodiment. The pulse sequence U ₇ Ct) in turn corresponds to the Λ pulse sequence U ₁ Ct) according to FIG. 2 (speech signal). The pulse train UgCt) serves as a sampling pulse train for a signal with half the bandwidth of the speech signal. The further pulse trains U _Q (t) to U ₁₁ Ct) are again used to transmit measured value signals with a bandwidth of 800 Hz.

The invention can be particularly advantageous in telemetry use, in the case of the person to be monitored, continuously important body function data via electrodes attached to the body, such as EKG, breathing rate, pulse rate or the like., removed and transmitted to the monitoring station via measured value signal channels and for which a speech channel is provided, about which this person also reports on each Transfer the activity carried out, e.g. running, rest, etc. can.

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Claims (6)

Claims UJ Device for the transmission of signals of different bandwidths, in particular voice and measured value signals, in which the individual samples are sampled at different times
different signals these are transmitted over a common transmission path to a receiving device and separated there again by appropriate sampling, characterized in that the sampling frequency for the signals with a larger bandwidth is selected to be correspondingly higher than for signals with a smaller bandwidth
Bandwidth. 2. Apparatus according to claim 1, characterized in that the sampling frequency for each signal corresponds to at least twice the value of the bandwidth of this signal _o 3 ο device according to claim 2, wherein the duration
a sampling is determined by the duration of a sampling pulse, characterized by the fact that the sampling of the signal with the largest bandwidth, for example
Speech signal based on a sampling pulse sequence (eg «U-) with a duty cycle of 1: 1 and the sampling pulses (eg Up to Ug) for the signals with a smaller bandwidth are distributed over the individual pulse pauses of this sampling pulse sequence according to a preferably regular scheme. · 4. Apparatus according to claim 3, characterized in that the first pulse of the sampling pulse sequence (e.g. U «) for the signal with the next lower bandwidth In the first pulse pause of the AbtSStimpulssequence (e.g. U ₁ ) for" the signal with the largest bandwidth is laid. 209838/0987 5. Apparatus according to claim 4, characterized in that the first pulses of the further sampling pulse trains (e.g. υ, to UV) one after the other into the other, still free Pulse pauses in the sampling pulse train (e.g. U ^) for the signal with the greatest bandwidth. 6. gate direction according to claim 1 to 5 »characterized in that that when a voice signal is transmitted together with measured value signals, the sampling frequency for the voice signal preferably 8 kHs urid for each measured value signal is 1.6 kHz. 209838/0987 Blank page