DE1262332B - Method and circuit arrangement for demodulation for frequency shift key telegraphy - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

H04b

H041; H04j

German class: 21 al -7/03

Number: 1262 332

File number: M 57050 VIII a / 21 al

Filing date: June 1, 1963

Opening day: March 7, 1968

The invention relates to a method for demodulation for frequency shift key telegraphy according to a system in which the various signal elements can be identified by their frequencies, as well as a circuit arrangement to carry out this procedure.

Known demodulators for such telegraph signals are mostly made up of resonance circuits or devices which respond to the signal frequency used. Such circles or devices take a considerable amount of time to build up their tension. The current needs require demodulators that are very fast, especially when it comes to data transmission can work. In fact, the working hours required are systems that use radio links or Use carrier frequency links, in the order of magnitude of a period of the carrier frequency used. Known common demodulators with tuned circuits are for such high speeds not suitable, and it is doubtful whether an advancement for speeds at where the signal element (character or pause) only consists of one or two periods of the carrier frequency, is possible. In addition, known demodulators are usually very sensitive to them the electrical constants of the channels to which they are connected and hold when switched from one channel to another rarely a constant error size.

The aim of the invention is to create a simple and a method for demodulation for frequency shift keying telegraphy, which is also suitable for high speeds and a circuit arrangement for performing this method, which is designed can be that it works satisfactorily even at these high speeds and without significant deterioration of the error size switched from one signal channel to another can be.

The demodulation method according to the invention is that the duration of the signal period the signals to be demodulated are compared with the duration of a period of a reference source, the frequency of which lies between the amounts of the identification frequencies assigned to the elements, and that depending on whether the duration of the period of the signal to be demodulated is greater or is less than the duration of the period of the reference wave, one or the other of two output signals is produced.

An advantageous embodiment of a circuit arrangement for performing this method is the method and circuit arrangement for
Demodulation for frequency shift key telegraphy

Applicant:

The Marconi Company Limited, London

Representative:

Dr. W. Müller-Bore and Dipl.-Ing. H. Gralfs,

Patent attorneys,

3300 Braunschweig, Am Bürgerpark 8

Named as inventor:

Peter Kemp Roberts, Chatham, Kent

(Great Britain)

Claimed priority:

Great Britain June 4, 1962 (21454)

characterized in that the signals to be demodulated are sent to a device for deriving a short, a given value of the signal oscillation associated pulse per period are applied, that the output of this device with a control stage with three each having two states Timers is connected that the first of the three timers with each supplied pulse in his passes over the second state and returns to its first state after a specified time, that the second timer each time the first timer returns to the first state in its passes over the second state and returns to the first state after a specified time, that the third timer changes to its second state each time the second timer returns and after a predetermined time it returns to the first state that the output of the second timing element with a first gate circuit and the output of the third timing element with a second gate circuit is connected, which also derived from the signals to be demodulated Pulses are fed that the outputs of the two gate circuits to one depending of the input variables one of two output

809 517/496

Signals generating device are connected and that the sum of the times in which the first and the second timing element are in their second state, substantially equal to T, the time in which the first timing element is in its second state, substantially equal to t ₂ , the time the second timer is in its second state is substantially equal to T- ₁₉ and the time the third timer is in its second state is substantially equal to t _t -T , where i _x and t ₂ are the period durations of the lower and upper frequency limits of the signals to be demodulated, and T represents the duration of a period of the reference wave.

Another advantageous embodiment of a device for carrying out the invention The method is characterized in that the signals to be demodulated to a device for Derivation of a short pulse associated with a given value of the signal oscillation per Period are created that the output of this device with a control stage with two each two States having timers is connected that the first of the two timers is supplied to each Impulse goes into its second state and after a given time back into its first state returns that the second timer with each return of the first timer in the first state goes into its second state and after a predetermined time again into the first state returns that the output of the second timing element with a first gate circuit and the output of the second timer is connected to a second gate circuit, which also pulses derived from the signals to be demodulated are supplied that the outputs of the two gate circuits to one of two output signals depending on the input variables generating device are connected and that the time in which the first timing element in its second _-, " State is essentially equal to the period of the reference source and the time in which the second timer in its second state is substantially equal to the difference between the Period of the lower limit frequency and the aforementioned time period.

Preferably, the signal pulses fed to the gate circuits are the same pulses as the first of the series-connected timers are supplied.

A particularly advantageous circuit arrangement for a frequency shift keying telegraph system in which the Period of the upper limit frequency is not greater than the difference between the said Period duration and the period duration of the lower limit frequency, is characterized by two gates, to which pulses are fed and whose outputs control a bistable unit that is dependent on of their state provides the output signals, as well as in that the output of the penultimate timer is used to control both gates while the output of the last timer controls only one of the two gates, causing simultaneous opening both gates are excluded.

Further details and advantages of the invention _r * are explained using the drawings below; in this show

1 to 3 are schematic diagrams for explaining the method according to the invention and

4 shows a simplified block diagram of an embodiment of a circuit arrangement for Implementation of the method according to the invention.

In the case of a frequency shift signal, the frequency changes from one value to the other or back, depending on whether the signal element to be transmitted is "character" or "pause". 1 shows a conventional frequency shift keying system in which a carrier frequency F _c is modulated by a tone frequency F _m for the "character" and by another tone frequency F _s for the "pause". The outer frequency limits are .F ₁ and F ₂ . The greatest possible duration of a period in this frequency band is t _± = 1 / F ₁ and the smallest possible period is t _z = VF ₂ . Each frequency between F ₁ and F _c represents "signs" and each frequency between F _c and F ₂ represents "pause", where the crossover frequency (reference frequency) is F _c . If T is the duration of a period of frequency F ₀ , then all durations from t ₂ to T represent “pause” and all durations from T to t _{± represent} “characters”. This is shown conventionally in FIG. 2, in which the demodulator output is OFF is plotted as the ordinate over the time periods t ₂ , t _s , T, t _m and t _t as the abscissa. t _p t ₂ and T represent times as described, and t _s and t _m are the periods of the specified frequencies for "characters" and "pause". The rectangular dashed line shows the idealized demodulator output, in which "character" and "pause" are differentiated by the period durations.

In Fig. 4 a practical embodiment of a circuit arrangement according to the invention is shown, and FIG. 3 shows a number of curves for explaining the mode of operation of the circuit arrangement according to FIG. 4th

According to the F i g. 3 and 4 are a signal wave to be demodulated with a period t within the already mentioned limits in an amplifier 1 and amplified by a subsequent limiter circuit 2 rectangular shaped. Line (α) of FIG. 3 shows the signal wave before the boundary and line

(b) afterwards. The limited wave is fed to a differentiating network 3, which derives from it pulses of opposite polarity, as in line

(c) the Fig. 3 is shown. From these pulses, 4 pulses of only one polarity - in the case described, the negative pulses - are selected by a pulse selector and these are made rectangular by a pulse shaper and inverter stage 5. The output of this stage 5 is shown in line (d) in FIG.

The pulses from the stage 5 to be a first timer Al fed to a known shape. Each impulse brings this member into its "ON" state during the time t ₂ , at the end of which the member itself returns to the "OFF" state. By means of a suitable pulse shaping circuit IAl , whenever Al returns to the OFF state, a pulse is formed and fed to a second timer A 2 in order to bring it into the ON state. A 2 remains in the ON state during the time interval T-t ₂ , after which it returns to the OFF state and derives a pulse by means of a pulse shaper IA 2 which brings a third timer A 3 into the ON state. A 3 remains in the ON state for the period t _t -T.

It is to temporarily the in F i g. 4 connecting line drawn in dashed lines not taken into account

1 226

stay (it represents a slight modification). The pulses from stage 5 are also fed in parallel to the two gates Gl and G 2, which are controlled by the elements A 2 and A 3, respectively. If A 2 is in the ON state, it opens Gl and closes it again in the OFF state. The gate-controlled outputs control a bistable unit BS, which in one state at the output terminal OT emits a signal level characterizing the signal element "character" and in its other state a signal level characterizing "pause". The table below shows a complete sequence of ten pulses from level 5, assuming that the fifth, sixth or seventh pulse should represent "characters" and the remaining pulses "pause". The two states of the bistable unit BS are marked with 0 and 1 as usual.

pulse Al Al A3 Eq Eq Bistable unit
BS Break I. Break I. r ^L ON OFF THE END THE END LOCKED LOCKED _ 2. ON OFF A THE END OPEN MINDED LOCKED 0 Break i 3 ON OFF A THE END OPEN MINDED LOCKED 0 ■ characters [4. " ON OFF A THE END OPEN MINDED LOCKED 0 ί ⁵ ON OFF THE END A LOCKED OPEN MINDED ¹ 1 Character ^ 6. ON OFF THE END A LOCKED OPEN MINDED 1 1 7. ON OFF THE END A LOCKED OPEN MINDED ι. ί ⁸ ON OFF A THE END OPEN MINDED LOCKED 0 1 Break I 9. ON OFF A THE END OPEN MINDED LOCKED 0 j 10. ON OFF ON OFF THE END OPEN MINDED LOCKED ο I

If t ₂ <t ₁ - t ₂ , ie if 2F ₁ <F ₂ , then there is the possibility that both A 2 and A 3 are together in the ON state and therefore gates Gl and G 2 in an arrangement like the one described open together. This can be done by the additional connection shown in FIG. 4 is shown in dashed lines, must be prevented. This line leads from the output of / 4 2 to gate G 2 to prevent G 2 from opening when A 2 is ON.

In a simplified modification of the embodiment according to FIG. 4, the first timer A 1 (and its pulse shaper stage IA 1) is omitted and the time that A 2 is in the ON state is lengthened so that it is equal to the time T. The pulses from stage 5 are then fed directly to A 2. The remainder of the arrangement remains as shown. This modification works very satisfactorily when each signal element has an even number of periods. However, if there is an odd number of periods per signal element, this simplified modification causes a distortion of one period per signal element in one of the elements - in the above example the element »pause«. In many cases, however, this is irrelevant, since such a distortion can be compensated for by regeneration, as is used in known synchronous telegraphy systems, when the ratio of carrier to traffic speed is greater than 5.

The invention is eminently suitable for use at high operating speeds Switching elements and parts which are known per se and are available in a highly developed form, and provides demodulators that switch from one channel to another without worsening the error size can be.

Claims (8)

Patent claims: 1. Method of demodulation for frequency shift keying telegraphy according to a system in which the various signal elements are recognizable by their frequencies, characterized that the duration of a signal period of the signals to be demodulated with the duration of a Period of a reference wave is compared, the frequency of which is between the magnitudes of the elements associated identification frequencies, and that regardless of whether the duration of the Period of the signal to be demodulated is greater or less than the duration of the period of the Reference wave, one or the other of two output signals generated. 2. Circuit arrangement for carrying out the method according to claim 1, characterized in that the signals to be demodulated are applied to a device (2, 3, 4) for deriving a short pulse per period associated with a predetermined value of the signal oscillation, that the output of this Device with a control stage with three two-state timing elements (A 1, A 2, A 3) is connected so that the first of the three timing elements changes to its second state with each pulse supplied and returns to its first state after a predetermined time that the second timing element (A 2) changes over to its second state with each return of the first timing element and returns to the first state after a predetermined time, that the third timing element (A 3) with each return of the second timing element goes into its second state and after a predetermined time returns to the first state that de The output of the second timing element (A 2) is connected to a first gate circuit (Gl) and the output of the third timing element (A 3) is connected to a second gate circuit (G 2), which are also supplied with pulses derived from the signals to be demodulated the outputs of the two gate circuits are connected to a device (BS) which generates one of two output signals as a function of the input variables and that the sum of the times in which the first and the second timing element are in their second state is essentially equal to T, the Time in which the first timer is in its second state, essentially equals U, the time in which the second timer is in its second state is substantially equal to T-t ₂ and the time in which the third timer is in its second state is substantially equal to t _± -T , where t _x and U are the period durations of the lower and upper frequency limits of the signals to be demodulated and T represents the duration of a period of the reference wave. 3. Circuit arrangement for performing the method according to claim 1, characterized in that the signals to be demodulated are applied to a device (2, 3, 4) for deriving a short pulse per period associated with a predetermined value of the signal oscillation, that the output of this Device with a control stage with two timing elements each having two states (A 2, A 3) is connected, that the first of the two timing elements goes into its second state with each pulse supplied and returns to its first state after a predetermined time second timer (A 3) with each return of the first timer (A 2) goes into the first state in its second state and returns to the first state after a predetermined time that the output of the second timer (A 3) with a first Gate circuit (Gl) and the output of the second timing element (A 3) is connected to a second gate circuit (G 2), dene n are also supplied from the pulses derived to demodulationsaeiTSignalen that the outputs of the two gate circuits are connected to a device (BS) which generates one of two output signals depending on the input variables and that the time in which the first timing element (A 2) is in its second state is essentially equal to the period of the reference wave and the time in which the second timing element (A 3) is in its second state is essentially equal to the difference between the period of the lower limit frequency and the aforementioned time period. 4. Circuit arrangement according to claim 2 or 3, characterized in that the signal pulses which the gate circuits (Gl, G 2) to- are the same as those applied to the first of the series-connected timers will. 5. Circuit arrangement according to one or more of claims 2 to 4, characterized in that that the device for deriving the pulses from the signals to be demodulated from the series connection of a limiter (2), a differentiating network (3) and a pulse selector (4) exists. 6. Circuit arrangement according to one or more of claims 2 to 4, characterized in that the three timing elements (A 1, A 2, A 3) are connected in series and one between the first and the second and the second and the third timing element Pulse shaper (IAl, IA 2) is provided. 7. Circuit arrangement according to one or more of claims 2 to 6 for a frequency shifting telegraph system, in which the period of the upper limit frequency is greater than the difference between said period and the period of the lower limit frequency, characterized by two gates (G 1, G 2) , to which pulses are supplied and whose outputs control a bistable unit (BS) which, depending on its state, supplies the output signals, one gate (G 2) from the output of the last timing element (A 3) and the other gate (Gl) is controlled by the output of the penultimate timer (A 2). 8. Circuit arrangement according to one or more of claims 2 to 6 for a frequency shifting telegraph system, in which the period of the upper limit frequency is not greater than the difference between the said period and the period of the lower limit frequency, characterized by two gates (Gl, G 2) which pulses are supplied and the outputs of which control a bistable unit (BS) which, depending on its state, supplies the output signals, and in that the output of the penultimate timing element (A 2) is used to control both gates, while the output of the last Timing element (A 3) controls only one of the two gates, whereby a simultaneous opening of both gates is excluded. 1 sheet of drawings 809 517/496 2.68 © Bundesdruckerei Berlin