DE2536507C3 - Digital frequency-keying modulator - Google Patents

Description

'3 4.

The iTliiHlung uses a digital I lean /. Lu, Au-.luln an example of the connection is! in the

astungs modulator according to the generic term drawings and is then shown in more detail

les claim 1 described.

Such modulators are useful for modems, Ls shows

lic digital signal level on a data line in mo- 5 I i g. 1 the block diagram of a digital frequency

Julierlc sinusoidal signals on a telephone line and service modulator according to the present invention

inverted convert. Frequency modulation with a translator, a digital / analog converter

Usually depending on a single or linear phase filter,

given binary signal level I or 0 each one of F i g. 2 shows a circuit arrangement of the

two predefined sinusoidal frequencies. m shy away from digital / analog converters,

Frequency modifiers developed early on F i g. 3 shows a circuit arrangement according to FIG

were usually in the form of Analopiiodu- F i g. 1 provided binary phase filters,

formulators and contained a tension F i g. 4 shows the relationship in a diagram

more controlled. Multivibrator that creates a rectangular between separation and character level at the input

Frequeii7.tastiings-lmpuls7.ug generated. For this Im- 15 of the modulator and the sine wave at the output and

pulse train, higher harmonics were then output. 5 is a diagram showing in greater detail

filters and dispenses. Such modulators were very much explained the generation of the output wave,

large and expensive and are hardly used for the purposes of the in FIG. 1 frequency-keying modulator shown

modern integration technology contains a digital counting arrangement 20, an over-

adaptable. so setter 22, a stepped digital / analog converter

DT-OS 22 53 494 describes a device for 24 and a linear Prms filter 26. A transmission data frequency shift keying is described, which serves a similar line 28, via the different logical signal purposes, as the present ErCm level (i or 0 ) are created, forms the input dung. The device according to the DT-OS ver of the digital counting arrangement 20. The output line also uses an oscillator that operates with an exact output frequency of the linear phase filter 26, which, however, is a frequency keying modulator as a whole, whereby quenzteiler for the constant output of a large number of two sinusoidal frequency signals F ₁ or F ₂ , depending on the frequency is connected downstream. This frequency logic level on the transmission data line 28, on the divider, is followed by a frequency selector, each of which has a respective line 30. The line 30 can be connected to an incorrect one of these frequencies, shown in accordance with FIG. 30, via which the telephone line selects the level of the data input signal. Advantageous sinusoidal frequency signals to a demodulator (on the other hand, it does not appear to be more accurate, not shown from a large number) at the other end of the telephone line of overdivided frequencies each to be selected and carried out.

The digital counting arrangement 20 contains a character level by means of a purely digital counting arrangement a 35 trigger Füpflop 32, to which the transmit data line 28 and precise timing as the basis for each of the output of an oscillator 34 via a line 36 perform an output frequency to be output. serve as entrances. The output of the flip-flop 32 er-in Particular attention should be paid to an entry via a line 38. The flip-flop 32 changes multiple feasibility in as purely digital technology as possible - its switching state only when negative technology and easy adaptability to different 40 signal edges on line 36. The signal on the different purposes. Send data line 28 controls flip-flop 32 and is

An older frequency wave synthesizer was used to input the output signal from oscillator 34.

DT-OS 1512 172 described. This synthesizer switch the flip-flop 32 by means of the internal AND

is also used to generate logically linked by telegraph member 32a.

signals frequency-modulated waves. Its largest 45, the transmit data line 28, is via an inverter 40

Disadvantage compared to the aforementioned device for and a line 42 connected to an AND gate 44

Frequency shift keying is its oscillator, its frequency, its inputs through lines 36 and 42

quenz is linear depending on the strength of the and the output of an inverter 46 are fed,

signal applied to the input changes. With one of the controlled by the signal on a line 48

Such a circuit arrangement cannot be an exact 50. An AND gate 50 has lines 48 and 36

Frequency reference measure and no desired Fre- as inputs. Another flip-flop 52 is over his

The constant frequency of the output signals ensures both control connections and internal AND gates

will. 52a and 52b with the output line 36 of the oscillator

The object of the present invention is the gate 34 connected and with its own plus and

Creation of an inexpensive, simple Fre- 55 minus outputs via lines 53 and 54, with

frequency keying modulator of purely digital design and an output signal on the output line 54

Function; will give easy and practical adaptability that half the frequency of the oscillator 34

to different output frequency pairs that can be specified. An AND gate 56 has lines 38 and 54

should be feasible with him. Such a modulator as input lines.

The outputs of the AND gates 44, 50 and 56 are supposed to be a multitude of sine waves in digital construction Wave trains of the first frequency for the one binary connected to an OR gate 58 and continue over state and also a large number of Sinuswellcn- a line 60 with an 8-stage counter and deco trains clearly different from the first-mentioned sine wave coder 62. The counter and decoder 62 has the extracts distinguishable frequency for the second output lines 64 and 66 and is indicated by a deco binary state hand over. 65 affects the control control 68 so that it has output signals

The solution to this problem is in claim 1 on lines 64 and 66 with different numbers

marked. Advantageous refinements are generated by input pulses that are generated via the input

called the subclaims. Line 60 can be entered into the unit 62. the

I ^J

Outgoing loans 64 and 66 of the unit 62 go from that in FIG. De-internal linear phase filters 26 shown in FIG Latches within unit 62 hold operational amplifier 170, its output. The controller 68 acts on the unit 62 so that line 172 via a resistor 174 and a Koncin The output signal from the unit 62 is connected to the output line 30 on its output signal 176 Line 64 can be generated for 104 pulses, 5 is. The input line 90 of the filter 26 is via a which are input via line 60, and that potentiometer 178 and a resistor 180 with a an output signal via line 66 for 114 pulses is connected to line 182, which via a resistor 184 can be generated on the input line 60. The and a line 186 to the operational amplifier 170 Control 68 can have various input leads. A capacitor 188 is between the lines signals, for example via lines 7On, 70 /), 7Or, io 186 and 172 and a resistor 190 between the Lei-7Oi / and 70c. The lines 70i / Hingen 172 and 182 are laid. A capacitor 192 is and 70 /) form the two inputs of an OR between line 182 and earth Glicdcs71, whose output line is line 48. tet.

The lines 64 and 38 feed the inputs of a generated during operation in the FIGS. t, 2 and 3 ge

AND giicdcs 72 and lines 42 and 66 the 15 showed modulator sine signals over the output

eincs AND gate 74. An OR gate 76 has the line 30, which in its frequency with the over the

Outputs of AND gates 72 and 74 vary levels inputted as inputs Sendcdatenlinie 28,

and its output line 78 is connected to the input The Sstufigc counter 62 controls the output fre-

Switching connection of a Zühlcr-Lösch-F lipflop 80 and quenz on line 30. It can be changed by varying the

connected to an input of a 4-step counter 82. 20 levels on one of the lines 10a to 7Oe overridden

An inverter 84 with line 36 at the input is about to be.

its output line 86 to the reset connection. For purposes of illustration, it is assumed that the circuit in the

of flip-flop 80 and the output of flip-flop 80 via the modulator shown in FIGS. 1, 2 and 3 so that

the line 88 to the reset terminal of the Sstufigcn that it produces the same output frequencies as that

Counter and decoder 62 connected. 25 well-known analog modem »Bell 202«. On the line

The 4stuligc counter 82 is via the output position- 70c is a raised control-

gcu H ', .V,)' and Z with the translator 22 and this level entered. According to the modem »Bell202«

with its output lines /?. "A '_; “W ₂ and Λ, also generated by the one shown in FIGS. 1, 2 and 3 shown modules

connected to the D / A converter 24. A line 90 lator on line 30 at character level (1) on the

connects the D / A converter 24 with the linear 30 scan data line 28 and a sinusoidal signal of 1200 Hz

Phase filter · 26. at Trcniuingspcgel (0) on the transmit data line 28

The D / A converter 24 is in detail in FIG. 2 a signal of 2200 Hz. The modulator according to FIG. 1

and contains four transistors 101, 102, 103 and up to 3 provides an output signal 30 '(see FIG. 4)

104. the one with four resistors 108, 109, 110 and 111 via line 30, which has a lower frequency F ₁

are connected in series. The resistors 108 to 111 35 at characters has in contrast to the higher frequency

are via a line 112 with an external span / ■ "., in the event of separation.

power source 113 connected. Four more transistors to supply Siiuissignalc on the output line 30 mil

116, 117, 118 and 119 are to be given a / an with the tran- different frequency, will be the

sistors 101 to 104 connected in series. The collect counter 82 pulses on line 78 from the rest

Gates of the transistors 116 to 119 are fed to members of the digital part 20 via the line 40. He counts dabs

90 connected, which the output line of the D A- binary upwards and generates corresponding binary

Converter 24 represents. A load resistor 120 is signals II ". Λ",) "and Z ' via its Auseangsleitun

/ placed between line 90 and earth. gen II '. .Y. ) 'uiul Z (see Fig. 4). Wehreiufsigrude W

The lines W ₁ . R ₁ . R ₃ and R. _x are the input V. V and /. ' mil increasing binary widths of the

lines of the D A converter 24. The line K ₁ is supplied to 45 inputs of the translator 22, values

Via an inverter 122 and a resistor 124 with this first up and then vice versa down to 0

connected to the base of transistor 116. In the same with its output signals W ₁ ', Λ.,'. Λ '., And /?'., Practice

Way is the 1 citung R., via the inverter 126 and the lines W ₁ to Λ, again "represent binary values

Resistor 128 to the base of transistor 117. the miles. The counter 82 cycles through Zci during this

1 eitunt: R ₃ via the inverter 130 and the contradiction so a complete cycle of 16 values. The Conver

132 to the base of transistor 118 and line ter 24 sets a sinusoid based on the values above R.

/ C ₁ via the inverter 134 and <. \ Cn resistor 136 with up / C ₁ digitally together. Its output is canceled

connected to the base of transistor 119. graduated wave 9t) ¹ . those in Figs. 4 and 5 / u sclici

The bases of the transistors 101 to 104 are / usam- is and the Smuswellc 30 'is approaching. The linear «

and connected to line 138. 55 phase filter 2 <i removes the steps of the curve 90 'uiu

Line / CiH-IiIi ₁ VIe 140 is / wipe the lines 112 ei.'eug! the analog sine wave 30 '.

and 138 and a resistor 142 / wipe the line If a 1 size (0) over the line data line

US and 1 never provided. 28 is entered, the ΙΊίρΙΙορ 32 is switched off

1 ine / ene diode compensation unit 144 is λλ and the level on division 38 is therefore reduced. You

the line 138 connected and '.inif.iiM the li.m- ν at κι also dci 1 mgang des'invcrters 41) switched off

sMoien 147. 148. 14 *> and 150. die. with the WideisoJaUJei I in a leraiisgang with the I citung ~ 42

stands 153, 154, 155 and 156 on / on connected in series, S.mimi leilci 'the AND gate 44 on 4 MH /

sJuhci. with the leadership 138 veibimden -πκί The Suva! \, -in ι K., 1Lu, μ .14 iilvi expands the ODI R-Glio

liansistoicn 14 * ¹ to 150 graze individually iibei the I ei- M), ί: ".'ahlei d2

Hingen, V ₁ Ns R ₁ gesteueil Die Niisgangeder lmeile · (·. ·. L \ ·,. '., 1-, Ic; (, 2 -! Em simple binary mMci and ei

i ::. 12 (1 IV) and 134 s, n, l da.-uiilv. W ide ^ i.-.- ule IhO. ear, e-, · :, |. " _pi \" he, J, c I eilune M allei I I-1 Per

Ki2 1t> 4 i-.iul IWi nut Jen Β. ·, Μ ·· ι dei 1 ii "> M, ^" i 14 "-Λ- J _1. U _v - ■ 1!., Ι, ■: m , m _U | s \ om Os-, ΙΙ.ιΐοι 34 ulvi di

l'-i ^ lvcbniJer Ic ·· ■■■ .. · (. () M _V ; Jv'l ciluin · 42 luvt ν »· ιι Invei ler 4

the raised level. The AND gate 74 and the OR gate 76 thus send the pulse beginning at the position 114 of the counter 62 over the line 78. which then switches on the flip-flop 80. The signal via its output line 88 cancels the Counter 62 again shortly thereafter. For this purpose, the inverter 84 is arranged between the oscillator 34 and the flip-flop 80, so that the flip-flop 80 and thereby also the counter 62 are cleared again at a suitable point in time will.

The pulse on the line 78 is fed in parallel to the counter 82, so that the latter advances one step. For every 114 steps of the counter 62, a

Give an impulse to the line 78 as just described, as long as the separation level! is on the transmission data line 28; all further pulses via the line 78 increase the status of the counter 82 in each case by one step. The counter 82 is also a simple binary counter and supplies the signals on its output lines IK, Λ ', Y and Z as shown in FIG. 4. It counts in binary from 0 to 15. Then counts up again (and so on.

The translator 22 is designed so that it au! the signals R, \ R ₂ ', _R:,' its Ausgangslcitungen with increasing Zählstaiu in the counter 82 and R ₁ 'are according to dci following table:

Table A.

State output voltage of the output of the

D / A conv. 24 translators

Issue of the payer 82

0 0.000 1 0.080 2 0.300 3 0.620 4th 1,000 5 1,380 6th 1,700 7th 1,920 8th 2,000

R \ R-.I R ₂ ' Λ. ' W. X Y ' Z ' and W. X ' Y ' 1 Z 0 O O O O O O O and 1 0 O O 1 O O O 1 and 1 \ O 1 0 O 1 O O O 1 O and 1 1 O O O 1 O O O O 1 1 and 1 1 1 1 I. O O O O 1 O O and 1 1 1 O I. O 1 1 O 1 O 1 and 1 O O 1 I. 1 O 1 O 1 1 O 1 O O 1 1 1 O O 1 1 1 1 O 1

0 0 0

AY

0.080 full 0.300 full 0.620 full 1,000 full

As can be seen from Table ¹ above. the output of the translator 22 is a binary · Ό ". if the output from the counter 82 is binary ■ · (> · ■. The counter K2 is a binary / counter and the signals K ','. V /.) ',' and /, 'are binary signals. Strictly speaking, the signals AY-AV. AY and Ii, are ki'ine binary signals. For a simpler description, they may be called "Ühciscl / Ie Kinai / ahk'U"! will. Both the! "'Bcisctzci 22 and the / ählei H2 both have the binary output I and the hiiiäicn Aiisi.!, Ilii .- \ M.-i | 2. those in the Ί alielle dem / iisl.iiid I or 2 enlspreehen. / In the same / eil. / U ilei di'i / ählei H2 aiii binäi 3 schalle !, the output of I bciscl / ei '. 22 is lunar -I. What your / iisland 3 eulspiuhl If der I ₁ IiIt; ill des / älilcis S2 on -I fails, the output de ^1. ('bi'i-, el / eis beieil · · aiii K. «, r · dein / inland 4 glcn hkoiiiml \\ run dei liihall di ". / ahlci.« 2 aiii binäi the output of the translator 15 is reached when the content of the counter 82 as shown in the table is an 8. When the number in the counter 82 goes to 9 (1001 binary) , the output of the translator returns to 14 (binary II 10); this then equates to the state 7. While the reading in the counter 82 continues to increase in liner intervals, the output of the translator 22 is already decreasing again in larger increments shown in the table.

The digital ¹ analog signal generator 24 outputs voltages on the line 90, which are given in the table below for each output of the report 22 over the lines Ii to Ii ₁ . These are the voltages 0.000. (I.OKO. 0.300. Od.'O, 1.000, 1.3KO. 1.700. 1.920 and 2.00 (1 on position 90 for states O to H. The respective voltage I ami at cc Ii nc! η man da · signal R ₁ ' al, a voltage, of 0.0X0 full, the signal Ii. al ·, a' .pan intimate, of 0.300 VdIi. the signal Ii ₁ ' mil O.fi.Vl Viii and the signal H, mil 1,000 \ Ί> || weiiei The tensions

!-'one. ivlil, he edition of I'beiset / ei, 2

what that
are in ile

u. country
I,! Bell

5 en
. ¹ ilai i

'.pm hl I) ie / u .lande <> esii.-lii Del / ii .laud K. b

A '

R ₁ ' to Ri' 'and to addicieu.
■, land ft ζ. H. (in which the Sii'uali
si hall! are) \ im I .VOH Yi> Ii ei gilii
Voltage K ₁ " ■" UO OMI YdIi. Del
0.fi20 VnM and dei Sp.iiiniiui ' Ii ₁
The W 111.ung .'.'- ei ed ··.

.pa

A ',' and A ", ''.

'Ii al ·. ΊιιιιΐιΊΐ

. I .111IMIII) 'A' 1

Ii ₁ min I 0110 VdIl
i'.et ic-i ·. 24 dei iIm

supplies all voltages for the states 0 to 8 on the line 90 , can be easily seen in connection with the circuit description in FIGS. 2 understand. A positive Spannimgspegel is applied via line 112 from the voltage source 1 13, and the Zener diode 140 and the resistor 142 provide a stable voltage on the line 138 to the bases of the transistors 101 to 104. [The transistors 101 to 104 constitute four independent power sources , where resistors 108 to 111 determine current values / "/. ,, I ₃ and /, for these current sources. The transistors 116 to 119 switch the currents / ,, / », / _{: 1} and /, these current sources via the load resistor 120 under control of the input signals on the lines Λ, to Λ, through. If the signal on line R ₁ is 0, for example, while raised signals are on lines R ₁ , R> and R _{: i} , only transistor 119 conducts, so that the current /., Through load resistor 120 and one Voltage generated between ground and line 90. This is the voltage of 1,000 volts given for state 4 in the table above. In the same way, the signal 0 on the lines R ₁ , R ₂ or find current / ,, /., Or Α, through the load resistor 120 , the effects of the signals R ₁ ' to R ₁ ' adding up. The resistors 108 to 111 are dimensioned so that the voltage generated on the line 90 across the load resistor 120 for the four signals R ₁ ' to Λ', '0.080, 0.300, 0.620 and 1,000 volts.

The transistors 147 to 150 and the corresponding resistors 153 to 156 compensate for inaccuracies that arise in the base circuits of the transistors 101 to 104. which change the current through and the voltage across the Zener diode 140 .

The stepped curve 90 'has the basic shape of a sine wave, as shown in FIG. 5 is shown. It explains the output of the D A converter 24. While the states 0, 1, 2, 3, 4, 5, 6, 7, 8, 7, 6, 5, 4, 3, 2, 1 and 0 with increasing counters of the counter 82 successively, as can be seen from the table Λ, the stepped sine wave 90 'is generated as shown in 1 ·' i g. 5 is shown.

The linear filter 26 smoothes the sleeve stepped voltage curve 90 'so that they contain as curve 30' on the output line 30 of the g in Fi. I to 3 shown modulator appears. E- "The separation level on line 28 is the frequency of the sinusoidal signal on line 30 2200 II /, which is obtained by dividing the frequency of 4 MIIz by 114 and a further division by 16. The division by I 14 is on the / ähk-r 62 and the division by Ki to ^ n / abler 82. For corresponding representations of the / calibration level and the Trcunungspegcls 28 ', the signals M "to /'. the signals Λ ',' to λ ¹ , ', the signal 90' and the signal 30 'can be shown in FIG. Ί can be used and from this it can be seen how input linear signals output analog signals with the I i) ',. I to 1 shown (iciät generate.

If / eichcnpcgcl (I) is on the transmitter signal 28, Jas I lipllop 32 with the next negative I lanke of the signal from (hzillalor 34 switched on Dlt I ι Ig [ ¹ Ci 52 i'.l the same Hanau wiedei I rigger 32nd His \ ii'.gange are veibiindeu with their inlets as shown.I ι schalli'l unier Ansloll des Os / ilialoi s.14 continuously back and forth and thus gives an output signal to its Niisgangsleiliing 54, which is half the I 'leqiieu / von · Ι MIIz. 11. II. 'Mil · has. The I IND- (iheder 44 and 74 bumps are now blocked by the lnveik'i 40, since the character level is present on the line 28. The AND element 56 is indicated by i \ cn The signal with half the oscillator frequency from the trigger 52 runs through the AND element 56 and the OR element 58 to the counter 62, which thus only counts half as fast as before at the separation level on the line 28.

One pulse of every 104 pulses which are fed to the counter 62 via the input line 0O appears on the output line 64 of the counter 62. The AND gate 72 is prepared by the signal on the line 38 from the flip flop 32 in the switched-on state. The pulses on the line 64 are thus given through the AND gate 72 and the "OR gate 76 on the line 78 , which, as is known, make the counter 82 count and the sine output wave 30 ' through the action of the translator 22, the" D / A converter 24 and the filter 26 generate. However, the frequency of the sinusoidal signal 30 ' on the line 30 is used for character

level is reduced from 2200 Hz to 1200 Hz in that the signal is applied at half the frequency on the line 54 to the counter 62 and that instead of the M4 counting line 66, the 104 counting line 64 of the counter 62 is used. The frequency of 1200 Hz

This gives you by dividing the frequency, from 4MHz through 2, 104 and Id.

The in the F i g. The modulator shown in FIGS. 1 to 3 can generate sinusoidal frequencies on the output line 30 for those specified below in the USA

3 "common modem types vr

Table B. / oak (»1«) Ticniumg (> () ") 35 modem type 1200 H / 2200 Hz Bell 202 1300 Hz 2100Hz Mini-12 1400 Hz 2000 11 / ⁴⁰ mini-6 1270 Hz 1070 Hz. KU normal 2225 Hz 2025 W /. 103 Answer

So far it has been described how the in ilen F i g. I to J Shown modulator output signals with 1200 µm: 22 (K) IIz so that it can carry out the tasks of

5 '> divider, of the analog modem Bell 2 () ί can carry out output signals with 1300 Hz and 2K) O W /. for the application Mini-I2 are generated in a similar way. I s, however, a signal is input via the Mini-12 line 70i / instead of via the Bell 2O2 line 7Oc

ΛS This will change the effect of the counter and deco dieters 62 changed so that it gave impulses to the divisions 64 and 66 for% b / w. I 19 gives a finger pulse which take the place of K) -I and I 14 impulses, dii were necessary for the '' MiWendung Hell UP. Dii

^fl "- ^{ll) 0} M / for lieniniiigspcgel on the Sciniedalenleiuiu;. 28 rcsiiltieicn thus from a division of the output ¹ by 4 Ml I / of the oscillator 34 by II ¹ ) and you I Hi The signal from IUH) II / results from a Divide the output of I \ | 11 / of the oscillator 34 by 2

'\ ^r , Wi and Id. The unseen output signals ν οι IHHI II / and. ¹ O (K) || / ,,, if of the line 3IM> cim Modiilaloi In the Miiu-d application differentiates it from the anweiiduimen Mini-12 times IU-II. "! 02 mn

by the fact that a signal is au! ' the management 7Or anstalt is entered on lines 7üi / or 70t · and thereby unit 62 one pulse on line 64 of every 89 input pulses and one pulse on the Line 66 generated every 125 input pulse.

From Table B above it can be seen that.! the Output frequencies for the modem types I3ell 202, Mini-12 and Mini-6 are approximately 2: 1, where the separation frequency is less than twice the symbol frequency. This can do HipHop 52 on its output line 54 a hoop frequency generate at character level, while the full frequency output of the oscillator 34 for the separation frequency is used. In every potash, the counter represents and decoder 62 inputs the output so that the draw frequency is slightly less than twice the draw frequency.

From table B it can be seen that 1.5 is the 103 normal frequencies of 1270 and 1070 11z for character and hyphenation levels are relatively close and that the separation frequency is lower than the character frequency. The same is true for the 103 response frequencies from 2225 and 2025 11z. The normal frequencies are used when a 103 modem has a Initiates communication with another modem on the other end of the trunk line, and the 103-AiH word frequencies are used by the answering modem for retransmissions.

Because the 103 normal frequencies are close together and the 103 response frequencies too, the full 4MMz output of oscillator 34 will be both for the 103 normal as well as for the 103 response functions used. In both cases, a signal is given via the line 48, which the AND gate 44 blocks and the AND gate 50 prepared. The signal via the line 48 is supplied by the OR gate 71, either from the 103 normal line 70 /> or from the i03 answer line 70 ". The AND gate 50 is directly connected to the output of the oscillator 34 via the Line 36 connected. So the full frequency of the oscillator 34 is given to the counter and decoder 62 via the AND gate 50 and the OR gate 58 for the 103 functions supplied.

The input signal on the 103 normal line 70 /) controls the decoding in the unit 62 in such a way that that one pulse on line 64 of every 197 pulses via the king line 60 at the character level uiul Inipuls is generated on line 66 of every 234 pulses via input line 60 at disconnection level. This results in the separation frequency son 1070 I Iz on the output line 30 by dividing the 4 MIIz through 2.34 and then dutch I 6 with I help the counter 62 and 82. The drawing frequency of 1270 Hz results corresponding with divisions by 197 and Id.

If the 103-Anlworlleilung 70i / carries a raised signal, a pulse on the 1 number 64 of all 112 pulses via the input cable 60 and a pulse on the line 66 of every 123 pulses via the line 60 is emitted. The / calibration frequency \ on .1225 II / ui \ d the separation sequence sun 2025 Ii / on division 30 result from divisions by 112 and Id h / w. 123 and Id. For the MM conditions, the I lalbl'requiiency output of the Ihpllops 52 is not necessary, since in both the oak and licnuuiigsiicqucnzcn are relatively close to each other. The I leuuunnsl'icquen / is in every lall elw.is lower than the / marriage frequency. The / similar and decoder '^ adjusts them to these parameters

The controller 68 thus leaves a pulse on lines 64 and 6ό for the ones indicated below Pulse numbers entered via line 60 take place:

Table C.

liingcse held
Control line

Impulszaiil over line 60 for
every impulse on:
Line 64 Line 66

(with characters) (with separation)

70t 'for Bell 202 104 114 15 7Oi / füi Mini-12 96 119 70r for mini-6 89 125 70 /> for 103 normal 197 234 7Of / for 103 answer 112 123

Incidentally, the oscillator frequency of 4 MHz is set by means of the clip-flop 80 in addition to resetting the counter also used to reset the character trigger 32.

* 5 According to the task, the explained modulator is included Executed digital elements. The two counts 62 and 82 form a digital device for dividing the Frequency of oscillator 34. To generate sinusoidal signals on line 30 for transmission over a telephone line are suitable, the translator 22 and the D / A converter 24 are then behind the The digital output of the counter 82 is used to compose a sinusoidal wave (wave 90 'in the F i g. 4 and 5). The linear! 'Nasal filter 26 smooths the graded sinusoids so that they are in the shape of the ideal shaped sine wave appears (wave 30 'in Figs. 4 and 5). The counter 62 operates as a function of the existence of a character or separation level on the transmit data line 28 in two ways: It divides the Input pulses over line 60 each through one of two different denominators, so that character and separation frequencies can be output on output line 30. The one in the F i g. 1 to 3 shown modulator can be used for those cases in which clic separation frequency is approximately is twice the frequency of the drawing; the effect of the frequency divider flip-flop 52 is also used. In other cases where the character and separation frequencies on line 30 are closer together.

So different are the output frequency of the oscillator 34 for both the calibration frequency and the training frequency used directly.

In particular from I · 'i g. 5 it can be seen that the stepped shaft 90 'has sixteen steps. The pin frequency is equal to the fundamental frequency of the sine wave 30 '. The linear l'hasenliller 26 smooths the wave 90' into the sine wave 30 '. l ~> c \ - 1 VA converter 24 behaves independently of the input queries and works equally well at all frequencies

fi (i / en. which are entered into it.

The Dii'.ilalleil 20 of the modulator enables one small and packed modems in terms of volume. Ir can be implemented in an integrated Schaltbauvveisc that the chip-

GΛ are intimate at least i \ cr order, the same who also use modern computer.

In order to be able to carry out the described I unconditionally, the I Mieiselzcr 22 is made according to known ΙΊ111-

13 ( ^U

zipicn built. See da / i itrodiiction To Ί lit- TIiciua luhrhar. «-Lic aulge / dt'l are in» Operational Ainplj-

Of Sviiching Circuits «, by [I. i. McC'hiskcj. Ik'rs. Pcsign And Applications ,, by Jerakl (].

McGraw-Hill Hook Company, (op.wiehi (, racnie. C icnc I ο b e y and. Awrencc | \

19Γ.8Γ especially Chapter IV. The linear l'havjn- II u «■ · I ^ ■"^{; 1} "· ^ν " ^{|: 1} ^ VU; i «-aw-ihll Hook (-." Iipany,

filter 26 is also selected according to known principles (c »p> riflil I "7I: especially Chapter VIII.

For this purpose 4 sheets of drawings

Claims (6)

! »Patent claims: 1. Digital frequency keying modulator for outputting sine wave signals as a function Signal levels of variable frequency supplied by the modulator input, with a driving Constant frequency oscillator, a counting arrangement and synthesis circuits at their output a siiuisoidalen output signal that initially grows in stages and then also falls again Can be removed in the course of the that the output of the oscillator (34) of constant frequency is a first counter (62) with two outputs (Lines 64, 66) is connected downstream, at the first output (line 64) at a first characteristic number of input oscillator pulses a first count signal and its second Output (line 66) at a second characteristic number of input oscillator pulses a second counting signal can be removed, that a signal level (1 or 0) fed to the modulator input is controlled standing selection circuit (AND gates 72, 74) is provided, via which the first output (line 64) of the first counter (62) when a first modulator input signal level is present and the second output (line 66) of the first counter (62) when a second modulator input signal level is present can be connected to the input of a second counter (82), 35 that the outputs (W, X, Y, Z) of this second counter (82) are connected to the inputs of the synthesis circuits (22. 24), and that a selective decoding control (68) is provided for the outputs of the first counter (62), with the help of at least one of the two characteristic numbers of input oscillator pulses marking counts is variable. 2. modulator me claim 1, characterized in Dall at the outputs (W, X, \\ /.) Of the / wide counter (82) removable count signals (W ', X', K ', Z') Binärsignalwerte (1 , 2, 4, ...) are 3. ' Modulator according to one of the preceding claims, characterized by a filter (26) to which the step-shaped output signal (90 ' ) is fed with a sinusoidal curve from the synthesis circuits (22, 24) and which has a smoothed, ideal sinusoidal signal (30) at the filter output (line 30) ') makes it removable. 4. Modulator according to one of the preceding claims, characterized by one between the Output of the oscillator (34) and the input of the first counter (62) provided, optionally switchable Frequency divider (flip-flop 52), with the help of which at least one when switched on of the two characteristic numbers of the first counter (62) inputted oscillator pulses later than when the frequency divider is switched off. 5. Modulator according to one of the preceding claims, characterized in that that the synthesis circuit consists of a translator (22) and a downstream digital / analog converter (24) exist and that the translator (22) has inputs connected to the outputs of the second counter (82) and outputs connected to the inputs of the converter (24), the translator (22) each having a single signal or a combination of the inputs of the converter (24) Signals (/ ?, 'to Λ ,,') can be supplied which are permanently linked to the output signals (W ', X', Y ', Z') of the second counter (82) according to predetermined translation relationships. 6. Modulator according to claim 5, characterized in that the following translation relationships given are: Edition of the ) (A ") second counter (82) > (Z ') 1 1 1 Edition of the ) (O Translator (22) ) (O Edition of the 0 0 1 1 0 0 0 Mixed lot (24) (W 0 (Y ') 1 and 1 I. 0 1 (R / 0 (R / 1 0 0 0 0 and I. 1 0 0 0 0 0 0 0% 0 0 0 1 and 1 0 1 1 0 1 0 0 4% 0 1 1 0 and I. 0 1 0 0 0 1 0 15% 0 1 1 1 and 1 0 0 1 0 0 0 1 31% 0 1 0 0 and 1 1 I. 0 1 50% 0 1 0 1 and 1 I. 1 1 0 69% 0 0 1 0 I. 1 0 1 85% 0 1 1 1 96% 1 0 L. 1 100%