US2469066A - Pulse multiplex receiver - Google Patents
Pulse multiplex receiver Download PDFInfo
- Publication number
- US2469066A US2469066A US673746A US67374646A US2469066A US 2469066 A US2469066 A US 2469066A US 673746 A US673746 A US 673746A US 67374646 A US67374646 A US 67374646A US 2469066 A US2469066 A US 2469066A
- Authority
- US
- United States
- Prior art keywords
- pulse
- pulses
- channel
- tube
- circuit
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J3/00—Time-division multiplex systems
- H04J3/02—Details
- H04J3/06—Synchronising arrangements
- H04J3/0602—Systems characterised by the synchronising information used
- H04J3/0614—Systems characterised by the synchronising information used the synchronising signal being characterised by the amplitude, duration or polarity
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J3/00—Time-division multiplex systems
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J3/00—Time-division multiplex systems
- H04J3/02—Details
- H04J3/06—Synchronising arrangements
Definitions
- the invention is particularly described in conn nection with an eight channel multiplex wherein the pulses are time displaced at the remote transmitter by the modulation.
- the transmitter which can be used is described in detail in copending application Serial No. 608.957, filed August 4, 1945 by W. D. Houghton to which reference is herein made, and its general mode of operation will now be given:
- the pulses corresponding to the separate channels are separately and consecutively generated at a fixed repetition rate known as the synchronization rate, corresponding to a iixed time interval which may be called the synchronization period.
- the synchronization rate is 10 kc. and the corresponding period 100 a sec. (microseconds).
- a pulse occurs once each synchronization period for each channel.
- each channel pulse occurs at a rate of 10 kc. and the .separation between adjacent pulses in each channel for an unmodulated condition is 100 n sec.”
- the pulses on each channel can be modulated *4 p. second (peak modulation) thus leaving a guard space between pulses from succeeding channels oi about 3.1 a sec. This guard space is important in reducing cross-modulation.
- the pulses from other channels occur in the interval between adjacent pulses from any one channel.
- the synchronization pulses occupythe ninth interval of 11.1 microseconds.
- the output pulses from the channels are of constant length and amplitude and the time between two adjacent pulses is measured from the leading edges.
- the modulation consists of varying the occurrence time of the pulses with respect to the synchronization pulse.
- the channel pulses may bev 0.4 microsecond long and the synchronizing pulse 2.0 microseconds. Thus, in each cycle or frame there are eight channel pulses followed by a single longer duration synchronizing pulse, and each such cycle or frame will consume 100 microseconds.
- the present invention relates to that portion oi the receiving system which converts the video 2 a pulses in the output of the receiver to a step volt age wave whose amplitude is adjustable over a small range and whose phase is adjustable with respect to the synchronizing pulse.
- video is employed to identiiythe nature of the voltages and currents in a circuit as consisting of D. C. pulses.
- the step voltage wave comprises a plurality of steps or risers of progressively increasing voltages, and each of these steps is utilized to cause a particular receiving channel to pass current (conduct).
- the invention also concerns that portion of the receiving system beyond the channel selector, wherein the pulses of varying occurrence time are converted to pulses of variable width whose variations in width correspond to the channel modulation.
- Fig. 1 illustrates, in box form, the complete receiving system for a pulse type multiplex communication system in which the invention is employed;
- Figs. 2a and 2b taken together are a series of curves graphically illustrating different voltage waveforms appearing in dierent parts of the receiving system
- Fig. 3a illustrates the circuit details of the apparatus coupled to the output of the superheterodyne receiver and shown in F18. 1 as the common unit;
- Fig. 3b illustrates the circuit details of the apparatus constituting a channel ⁇ unit of which there are as many as there are channels in the system.
- the pulses which the receiving system is designed to receive are short spaced pulses of radio frequency energy which are transmitted from a remote multiplex transmitter, not shown.
- These u1tra ⁇ short wave pulses may be in the form illustrated in curve A of Fig. 2a which shows eight channel pulses of short duration and one synchronizing pulse of longer duration for veach frame or cycle.
- the showing of curve A, Fig. 2a is for the condition of no modulation and is given by way of example only. It should be noted that the pulses are evenly spaced from each other.
- the pulses oi curve A, Fig. 2a are collected by antenna i9 and impressed upon superheterodyne receiver 2li, Fig. 1, the output of which is in the form of video pulses which may take the form shown in curve B of 2a.
- These video pulses are impressed vla lead
- This synchronizing pulse' separator cir- -cuit I, 2 suppresses the channel pulses because of the fact that the channel pulses are of shorterv In efj duration than the synchronizing pulse.
- the synchronizing pulse separator circuit comprises a pair of ⁇ vacuum tubes .I, 2 of which vacuum tube I serves as a limiter.
- the pulse generator 3, 4, 5 comprises three vacuum tubes whose functions willl appearin more detail later on in connection with the description of Fig. 3a.
- This pulse generatorin effect is a discharge pulse generator which produces a discharge pulse which is sent over two paths, one of which extends to the phasing trigger circuit 6, 'I and the other of which' extends via lead to a stepwave generator I I, I2.
- the phasing trigger comprises'two vacuum tubes 6, 1 which provide a pulse of adjustable phase for driving a 90 kc. exciter vacuum tube 8.
- This tube has as its output, a circuit 8 which is tuned to 90 kilocycles.
- the output of the 90 kc. exciter, as derived from the tuned circuit therein, is in the form of a 90 kc. sine wave, which is fed to a 90 kc. limiter 0, I0.'
- This limiter comprises a pair of vacuum'tubes 0, I0 which serve to convert the applied 90 kc. sine-wave to peaked positive pulses, in turn. applied via lead to the step wave generator II, I2.
- the step wave generator comprises several vacuum tubes which function toeproduce a step wave voltage having a plurality of steps or risers corresponding in number to the number of channels of the system.
- the discharge pulsev supplied from the discharge pulse generator 3, 4, 5 via lead I00 to the step wave generator serves to terminate the step wave voltage after a desired number of risers or steps.
- the output from the step wave generator is passed through a coupling vacuum tube I3 and then via lead I02 to the various channel selectors 2
- the channel selectors in the diierent channels are differently biased so as to become conductive on diil'erent risers or steps of the applied step wave voltage.
- the output of each channel selector is applied to ya trigger circuit 23, 24 which i-s in turn associated with a gate 22, the latter cl b
- variable width pulses from the output of the trigger circuit 23, 24 are supplied to a low pass filter 34 which removes all Vhigh frequency components and passes the audio signal to the audio ampliiler tube 21.
- Av ringing circuit 25,' 2l is also provided for calling the attention of the attendant when it is desired to apply ringing currents to a particular channel.
- receiving system has amplined the weak radio frequency pulses, converted them to D. C. pulses (video) and then supplied these pulses to the receiving multiplex at a suitable ampliiier level.
- the receiving multiplex system regenerates the synchronizing period (100 microseconds) directly from the incoming signal, and with it separates the channel pulses in the same order that they were originally generated. vThe separated pulses ⁇ are then demodulated to give eight voice frequency outputs.
- the synchronizing separator comprises a triode tube I normally .biased to out oil and also tube 2 which is coupled to the output of triode I through a di'erentiator circuit. Tube I acts as alimiter.
- the video pulses (curve B) from the radio receiver are applied to the grid of triode I.
- Tube I acts as a limiter and its output comprises spaced pulses whose polarity are reversed relative-tothe input pulses. These reversed polarity pulses in the output of tube I are differentiated C.) Tube 2 is also normally non-conducting;
- the discharge pulse generator comprises tubes 3,- 4 and 5.
- the output from the synchronizing separator, taken lfrom the cathode of tube 2 is a peaked pulse in the positive direction which gradually diminishes over about 33 microseconds, and this gradual diminution of the pulse is caused by the discharge time of the capacity to ground through the high cathode resistor 40 ofk vtube 2 and the grid of the following tube 3- in the dischargepulse generator. (Note curve D.)
- Tube 3 is normally non-conducting and the application of the positive pulse thereto from the synchronizing separator causes it to conduct, asa result of which a negative pulse of sloping trailing edge is produced on its anode (curve E) which causes a negative pulse (curve F) t9 be supplied to the grid of tube 4.
- Tube 4 is normally conducting and the application of a negative pulse thereto causes it tocease conducting for a short period of time, thus producing a positive output pulse in its anode circuit of about 3 microseconds which looks like curve G.
- Tube 5 is a coupling tube and is normally non-conducting. The application of a positive pulse to its grid from the yanode of tube l produces a discharge pulse on its cathode of positive polarity which looks like curve Pi'.
- the discharge pulse from the discharge pulse generator is supplied both to the phasing trigger and to the step wave generator.
- The'phasing trigger is a self-restoring trigger circuit having one degree of electrical stability and comprises tubes 6 and 1. vIn eect, this phasing trigger is nothing more or less than a delay circuit it will be seen that the (Note curve for delaying the pulses passed thereto by a predetermined amount. Normally. tube 6 is nonconductive and tube 1 conductive. When this trigger circuit is iired. it remains in its active l state for a time detennined by the time constant of the circuit. The amount of delay is adjusted by means of a tap on the anode resistor of tube 1.
- the positive pulse from the cathode of tube I of the pulse generator is applied to the grid of tube 6 of the phasing trigger and tires the trigger circuit to its active state.
- Output from the phasing trigger is taken from the common cathode circuit and xs primarily a negative pulse whose trailing edge has an overshoot or positive peak, so to speak, which is utilized to excite the A90 kilocycle exciter 8 (note curve J).
- the 90 kilocycle exciter comprises a vacuum tube 8 having in its anode a parallel tuned circuit I' whose resonant frequency is 90 kilocycles. 'I'his tuned circuit is loosely coupled to the anode of the exciter tube.
- the exciter tube 8 has a selfbias which adjusts itself so that it passes current only on the overshoot or peaks of the waves supplied to it by the phasing trigger. Note curve J. This overshoot occurs once each frame; or, putting it in other words, once for each synchronizing pulse but not necessarily at the synchronizing pulse time.
- the exciter tube passes current, it supplies a driving pulse or kick (curve K) to the 90 kilocycle tuned circuit 6'.
- This driving pulse or kick sets the tuned circuit into oscillations at a 90 kilocycle rate. These oscillations are of sine wave form and tend to decay slightly. In this particular case, the driving pulses from the 90 kilocycle exciter occur at intervals of 100 microseconds corresponding to a rate of 10,000 per second. Thus, one driving pulse is supplied to the tuned circuit for every nine cycles of sine wave oscillation generated in the tuned circuit. This is shown in curve L.
- the portion X of the curve J is adjustable by adjustmentv of the resistor I8 of the phasing trigger.
- the output of the tuned circuit l' is passed to the grid of vacuum tube 9 of the 90 kilocycle limiter.
- This tube passes only the positive halves cycle exciter; and the decaying amplitude of the pulse of curve M is caused by the inherent damping of the 90 kilocycle tuned circuit 8'.
- this 90 kilocycle tuned circuit 8' is maintained in oscillation by its exciting pulse.
- Tube 10 of the 90 kilocycle limiter converts the pulses of waveform M to more peaked pulses of wave form N.
- the negative going pulse of curve N is caused by the reaction from the step wave generator which is coupled to the output of tube I0 of the 90 kilocycle limiter.
- 629,169 corresponds tothe discharge pulse passed to the step wave generator directly from the ihode of tube 5 of the pulse generator over lead
- the coupling vacuum tube I3 corresponds to the cathode follower tube G of my copending application Serial No. 629,169.
- Step wave output is taken from the cathode oi this coupling tube and supplied via lead
- This step wave output supplied to the channel units is curve P.
- the channel units also have supplied thereto the video pulses from the radio receiver over lead IIII.
- 3 are connected to a common source of anode polarizing potential +290 volts.
- Triode tube I2 is biased by the resistorcondenser combination 4
- the grid of triode I2 is connected through a resistor 42 and a coupling condenser 43 to lead
- Each of thse input pulses (curve N) is of suill- ⁇ cient magnitude to overcome the cut-off bias of tube I2 and cause it to conduct for the duratio of the applied pulse.
- a storage or step condenser Il is connected between ground and the circuit combination 4
- a step wave voltage is built up across condenser M, and this step wave voltage has a plurality of steps -of increasing amplitude corresponding in. number to a desired number of input pulses (curve P).
- Tube II is a normally non-conductive vacuum tube which, when it conducts, serves to restore coupling condenser I3 to its original condition after each input pulse.
- the cathode of tube II is connected to the grid of tube I2, while the grid of tube II is connected via lead 46 to the circuit combination 4 I.
- Tubes a, b and c are normally non-conductive and become conductive simultaneously.
- the grids .of these tubes are connected together and their cathodes are also connected together and to ground.
- the space path of tube c is effectively across step condenser 44, and when this tube con- ⁇ ducts, it forms a low impedance discharge path cross condenser M.
- Tube b when it conducts, insures the quick discharge oi the load capacity connected to the cathode of tube I3.
- Tube a serves to prevent tube I2 from conducting during the discharge of step condenser M.
- " are differently self-biased, and each channel selector is normally biased well beyond the current cut-off condition.
- the channel selector is substantially like that shown in Houghton copending application Serial No. 608,957, supra, except for the fact that in the anode circuit, a coil 20 is used instead of a resistor.
- This coil 30, Fig. 3b is a differentiating coil and its purpose is to provide a much shorter pulse than that provided by the output of the channel selector described in the Houghton copending application.
- the channel selectors are differently biased to operate on successive risers of the step wave output (curve P) from the step wave generator II, I2.
- 02 is great enough to insure that during its occurrence the attacco current of the corresponding biased .channel .selector shall be driven rapidly from beyond the current cut-otr condition toa zero bias value.
- a channel selector which is normally cutoif, passes current, (it responds to the increase in voltage on the particular step rise), it will" continue to pass current until the completion of the step wave voltage.
- the dierentiated short pulse output from the channel selector 2l' is in the negative direction, as shown in curve Q, -for example, (corresponding to channel 4) and is passed on to a self-restoring trigger circuit com ⁇ prising vacuum tubes 23 and 24.
- Tube 23 of the trigger circuit is normally conilredv which is considerably shorter than the time allotted for one channel.
- res the trigger circuit to its active state, while the'gate 22 turnsL oil or restores the trigger circuit to its stable state.
- the output from the trigger circuit is thus a pulse oi variablewidth, depending upon the time interval between4 the channel selector output pulse and the incoming video signal pulse for that channel.
- , the gate 22 and the trigger circuit 23, 24 constitute in effect a system fori transforming the time-displaced video signalpulses to variable'widthv pulses, the variation in, width corresponding to the signal modulation at the remote transmitter which varies the timing of the transmitted pulses.
- f' low pass filter removes all high frequency corn-V
- the video pulses from the output of the radio non-conductive are of posi-- tive polarity and are not of themselves of sufli cient amplitude to make the gate 22 conduct.l
- the trigger circuit 23, 24 is red and is in its active state, there is supplied to the grid of the gate 22 over lead 3
- This positive voltage pulse from the trigger circuitl applied to the grid is of sutil-1 cient magnitude to reduce lthe cut-oil bias on the tube 22 to an extent such that if at this time a video signal pulse of positive polarity is also ap- ⁇ plied to the grid via lead lili, the resulting volt; age from both the video signal pulse and the ⁇ trigger pulse are sufcient to overcome the bias on the gate 22 and cause it to conduct. It will ⁇ thus be seen that only in the simultaneous presence of both the video signal pulses and a positivev pulse from the trigger circuit will the'l gate 22 of any one chanel pass current.
- Curve R illustrates the voltage wave forxn ap pearing on the grid of gate 22.
- the short sharp pulses correspond to the signal pulses and these short sharp pulses are not suiiicient of themselves to'overcome the cut-oi! bias of the gate.
- the large. longer duration pulse corresponds to. the voltage occurring on the grid of 22 due to the simultaneous application of both a video signal pulse and a positive pulse from the trigger cir- ⁇ cuit, and the peak of this larger amplitude longer duration pulse has a magnitude suilicient to overcome the' cut-oi! bias on the gate 22.
- Curve S shows the voltage variation at the common cathode of the trigger circuit 23, 24.
- the fixed edge is determined by the firing pulse for the trigger circuit 23, V24 supplied from ,the channel selector, while the trailing or modulated edge isdetermined by the -restoring pulse supplied ib the gate 22.
- Pulse rectifier tube 25 and rectifier tube 26 com-VV prisethe ringing system.
- the rectifier 25 has an input pulse supplied to its grid from the anode of tube 23 of the trigger circuit through a low pass nlter comprising a high resistance 35and a capacity formed by the grid-to-ground capacity of tube 25. The pulses from the trigger circuit.
- the wave vform at the grid of tube 25 has the form of the solid line of curve T.
- Pulse rectifier tube 25 is supplied with a floating ilxed bias from the rectier 26. This bias is adjusted to a value such that the pulse of the solid line of curve T causes conduction near the peak of this pulse.
- This conduction current ilows through resistance 36 in the cathode of tube 23' to a source of negative bias -10 volts.
- the con'- duction current through resistor 35 is suillcient to maintain the 4cathode of tube 25 at a potential in the neighborhood of +5 volts with respect to ground.
- i v l This bias is supplied to the grid of audio ampliiler tube 21 through a. lowlpass lter comprising resistances 31, 38 ⁇ and capacitor 39. This condition causes audio amplier tube 21 to conduct in normal fashion as an audio amplier.
- the ringing is nc-v eomplished by advancing a channel pulse to itl ananas extreme position, where it remains for the duration of a' ring.
- This ringing condition produces a narrow pulse at the anode of trigger tube 23 and this pulse, after passing the low pass illter to the grid oi tube 28, isof such low amplitude that it cannot overcome the ilxed bias on tube hence tubey 25 remains completely non-conducting.
- the voltage at the cathode to tube 2l is maintained at a value closeV to minus 10y volts with respect to ground. 'I'his condition provides this same negative bias at the grid of audio ampliiler tube 21 causing it to be essentially at cut-oli.
- a ringing relay In the plate circuit of tube 21 is connected, along with the audio output transformer, a ringing relay which is kept closed by the normal plate current of thisl tube. When this tube is cut 'oil'. the ringing relay opens and causes a twenty cycle ringing channel generator to be started and switched on to the outgoing line.
- a pulse multiplex receiving system for receiving from a remote transmitting system a plurality of equal duration spaced channel pulses followed by a synchronizing pulse, comprising a receiver for producing spaced video pulses which occur at time intervals corresponding to the received pulses, a separator circuit for separating the video pulse representative of the synchronizing pulse from the channel pulses, a discharge pulse generator coupled to said separator circuit for producing a pulse for each synchronizing video pulse supplied thereto, a phasing trigger circuit coupled to the output of said discharge pulse generator, said phasing trigger circuit having means for producing a peak voltage which occurs an adjustable interval of time after the pulse supplied thereto by saiddischarge pulse,
- a sine wave generator coupled to the output of said phasing trigger circuit and responsive to the peak voltage passed thereto, a limiter in the output of said sine wave generator, a stepA wave generator coupled to the output of said limiter and responsive to the limited waves for producing a step voltage wave having a desired number of steps or risers, a connection from the output of said discharge pulse generator to said step wave generator for controlling the termination of the step-voltage wave produced by said step wave generator, a plurality of channel units coupled to the output of said step wave generator, a connection from said channel units to the output of said receiver to obtain therefrom video channel pulses, said channel units having individual selector circuits which are differently biased to become conductive on diiierent risers of the step voltage wave, and said channel units having apparatus for converting the video channel pulses to variable width pulses.
- a receiving system including apparatus for producing D. C. pulses representative of said channel and synchronizing pulses, a circuit responsive only to the D. C. synchronizing pulse for producing another pulse.
- a discharge pulse generator coupled to said last circuit for producing a pulse in response to each pulse supplied to said generator by said last circuit, means for producing a voltage wave of adjustable occurrence time from the pulse produced by said pulse generator, a shock-excited sine wave generator coupled to said means for producing a number of sine waves corresponding in number to the received pulses tor each frame or cycle oi operations, a step wave generator coupled to the output of said shockexcited sine wave generator for producing a step voltage wave having a plurality of steps or risers corresponding in lnumber to the number ofreceived pulses for each trame or cycle of operations.
- a receiving system including apparatus for producing D. C. pulses representative of said channel and synchronizing pulses, a discharge pulse generator normally biased to cut-oi!
- a receiving system including apparatus for producing D.
- synchronizing pulse for producing a plurality of equally spaced waves corresponding in number to the number of channel and synchronizing pulses in each frame or cycle of operations
- said means including a shock excited damped tuned circuit and a circuit preceding said shock excited damped tuned circuit for varying the .phasing or time oi.' initiation of the equally spaced waves produced by said tuned circuit, a step wave generator coupled to said means for producing a step voltage wave having a plurality oi steps or risers corresponding in number f ll to the number-o1 received waves for eachframe or cycle of operations, a plurality of individual channel circuits coupled to the output of said step wavek generatorand a connection forv supplying D.
- channel pulses'to said channel circuits said channel circuits being so constructed i and arranged as to become responsive on dverent risers o! the step voltage wave, and having apparatus'for converting the D. C. channel pulses of varying Ioccurrence time to variable width pulses.
- a pulse multiplex system wherein a plurality of equal duration spaced channel pulses and a synchronizing pulse are transmitted for115 each frame or cycle of ⁇ operations and wherein the occurrence time of each channel pulse is va- ⁇ riable over a range -by the signal modulation for vidual channels, and causing different channels to become responsive at'difrerent times corre-3 sponding ⁇ to the occurrence time of the risers of said step voltage wave.
- the method of operation which includes receiving the transmitted pulses, producing from only thereceived synchronizing pulse a plurality of equally spaced waves corresponding in number to the number of pulses received during each frame or cycle of operations and commencing at an adjustable time after the receipt of said synchronizing pulse, producing from said equally spaced waves a step voltage wave having a plurality of steps or risers corre- ⁇ in number to the number ofi sponding in number to the'number of ceived during each frame or'cycle of operations, feeding the received pulses to a plurality of indie A vidual channels, causing different channels to become responsive at diierent times correspondingA to the occurrence time of the risers of said step voltage wave, and converting the received pulse
- receiving system therefor comprising a circuitfor separating the synchronizing pulse4 from .the channel pulses'.A an electron. dischargeV device biased to the current cut-oi! condition and a circuit therefor for producing sine waves.,l and means located between said device and: said separator circuit and responsive only to the separated syn-v chronizing pulse in the output oi-said separator circuit for producing a pulse -which overcomes said cut-of!
- said means including self-restoring trigger circuit having only one degree of electrical stability for varying the phasing or time of'initiation of said plurality of waves, and a ⁇ stepwave generator coupled to and responsive to the output of said means for producing a step voltage wave having a plurality of steps or risers corresponding in number to the pulses in each ⁇ frame.
Landscapes
- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Particle Accelerators (AREA)
- Channel Selection Circuits, Automatic Tuning Circuits (AREA)
Description
May 3, 1949. J. R. DAY
PULSE MULTIPLEX RECEIVER 5 Sheets-Sheet l Filed June 1, 1946 May 3, 1949.
J. R. DAY
PULSE MULTIPLEX RECEIVER Filed June l, 1946 5 Sheets-Sheet 2 ATTORNEY May 3, 1949. J. R. DAY 2,469,056
PULSE MULTIPLEX RECEIVER Filed June l, 1946 MTH/raf .fire-P MM' Giu-mme @LV-ww, voz M65/976m? INVENTOR Jal/ma'. lfy
BY /Qywm ATTORNEY May 3, 1949. J. R. DAY
PULSE MULTIPLEX RECEIVER 5 Sheets-Sheet 4 Filed June l, 1946 AAAAA SSG s AAAAA VVVVV May 3, 1949.
Fied June 1. 194s J. R. DAY
PULSE IULTIPLEX RECEIVER All..
E OUTPUT 5 Sheets-Sheet 5 Y JmL-Mg 794mm ATTORN EY Patented May 3, 1949 PULSE MULTIPLEX RECEIVER Janien a. my, recom, N. Y., mmm u aaai Corporation of America, a corporation of Deia- Application June 1, 1946, Serial No. 873,746
7 Claims. (Cl. 179-15) This invention relates to multiplex systems,
and particularly to the receiving portion of av multiplex communication system employing short pulses of electrical energy.
The invention is particularly described in conn nection with an eight channel multiplex wherein the pulses are time displaced at the remote transmitter by the modulation. The transmitter which can be used is described in detail in copending application Serial No. 608.957, filed August 4, 1945 by W. D. Houghton to which reference is herein made, and its general mode of operation will now be given: In order to achieve multiplexing, the pulses corresponding to the separate channels are separately and consecutively generated at a fixed repetition rate known as the synchronization rate, corresponding to a iixed time interval which may be called the synchronization period. In the transmitter, the synchronization rate is 10 kc. and the corresponding period 100 a sec. (microseconds). A pulse occurs once each synchronization period for each channel. The individual rates and periods of the channels are consequently the same and equal m the synchronization rate and period. Each channel pulse occurs at a rate of 10 kc. and the .separation between adjacent pulses in each channel for an unmodulated condition is 100 n sec."
(microseconds). Because the unmodulated signal pulses are similarly located in each channel, adjacent pulses from different channels are therefore about 11.1 microseconds apart in the common output circuit. The pulses on each channel can be modulated *4 p. second (peak modulation) thus leaving a guard space between pulses from succeeding channels oi about 3.1 a sec. This guard space is important in reducing cross-modulation. The pulses from other channels occur in the interval between adjacent pulses from any one channel. The synchronization pulses occupythe ninth interval of 11.1 microseconds. The output pulses from the channels are of constant length and amplitude and the time between two adjacent pulses is measured from the leading edges. The modulation consists of varying the occurrence time of the pulses with respect to the synchronization pulse. The channel pulses may bev 0.4 microsecond long and the synchronizing pulse 2.0 microseconds. Thus, in each cycle or frame there are eight channel pulses followed by a single longer duration synchronizing pulse, and each such cycle or frame will consume 100 microseconds.
" The present invention relates to that portion oi the receiving system which converts the video 2 a pulses in the output of the receiver to a step volt age wave whose amplitude is adjustable over a small range and whose phase is adjustable with respect to the synchronizing pulse. The term video is employed to identiiythe nature of the voltages and currents in a circuit as consisting of D. C. pulses. The step voltage wave comprises a plurality of steps or risers of progressively increasing voltages, and each of these steps is utilized to cause a particular receiving channel to pass current (conduct). The invention also concerns that portion of the receiving system beyond the channel selector, wherein the pulses of varying occurrence time are converted to pulses of variable width whose variations in width correspond to the channel modulation.
A more detailed description o! the invention follows in conjunction with a drawing wherein:
Fig. 1 illustrates, in box form, the complete receiving system for a pulse type multiplex communication system in which the invention is employed;
Figs. 2a and 2b taken together are a series of curves graphically illustrating different voltage waveforms appearing in dierent parts of the receiving system;
Fig. 3a illustrates the circuit details of the apparatus coupled to the output of the superheterodyne receiver and shown in F18. 1 as the common unit; and
Fig. 3b illustrates the circuit details of the apparatus constituting a channel `unit of which there are as many as there are channels in the system.
Throughout the figures of the drawing the same parts are designated by the same referencel characters.
The pulses which the receiving system is designed to receive are short spaced pulses of radio frequency energy which are transmitted from a remote multiplex transmitter, not shown. These u1tra`short wave pulses may be in the form illustrated in curve A of Fig. 2a which shows eight channel pulses of short duration and one synchronizing pulse of longer duration for veach frame or cycle. The showing of curve A, Fig. 2a is for the condition of no modulation and is given by way of example only. It should be noted that the pulses are evenly spaced from each other.
The pulses oi curve A, Fig. 2a, are collected by antenna i9 and impressed upon superheterodyne receiver 2li, Fig. 1, the output of which is in the form of video pulses which may take the form shown in curve B of 2a. These video pulses are impressed vla lead |01 upon a common unit common unit are first applied to a synchronizing pulse separator circuit l, 2 wherein only the synchronizing pulseis effective to produce apulse y which is applied toa `pulse generator circuitI 3,-"v
4, '5. This synchronizing pulse' separator cir- -cuit I, 2 suppresses the channel pulses because of the fact that the channel pulses are of shorterv In efj duration than the synchronizing pulse. r fect, the synchronizing pulse separator circuit comprises a pair of `vacuum tubes .I, 2 of which vacuum tube I serves as a limiter.
The pulse generator 3, 4, 5 comprises three vacuum tubes whose functions willl appearin more detail later on in connection with the description of Fig. 3a. This pulse generatorin effect, is a discharge pulse generator which produces a discharge pulse which is sent over two paths, one of which extends to the phasing trigger circuit 6, 'I and the other of which' extends via lead to a stepwave generator I I, I2.
The phasing trigger comprises'two vacuum tubes 6, 1 which provide a pulse of adjustable phase for driving a 90 kc. exciter vacuum tube 8. This tube has as its output, a circuit 8 which is tuned to 90 kilocycles. The output of the 90 kc. exciter, as derived from the tuned circuit therein, is in the form of a 90 kc. sine wave, which is fed to a 90 kc. limiter 0, I0.' This limiter comprises a pair of vacuum'tubes 0, I0 which serve to convert the applied 90 kc. sine-wave to peaked positive pulses, in turn. applied via lead to the step wave generator II, I2.
The step wave generator comprises several vacuum tubes which function toeproduce a step wave voltage having a plurality of steps or risers corresponding in number to the number of channels of the system. The discharge pulsev supplied from the discharge pulse generator 3, 4, 5 via lead I00 to the step wave generator serves to terminate the step wave voltage after a desired number of risers or steps.
The output from the step wave generator is passed through a coupling vacuum tube I3 and then via lead I02 to the various channel selectors 2|, 2|', 2|" of the diierent channe.1 units, it being understood that there are as many channel units as there are channels in the system; in this case eight channels. v
The channel selectors in the diierent channels are differently biased so as to become conductive on diil'erent risers or steps of the applied step wave voltage. The output of each channel selector is applied to ya trigger circuit 23, 24 which i-s in turn associated with a gate 22, the latter cl b|saining the signal or video pulses from lead 0 trigger circuit and gate are such as to convert the applied signal video pulseswhose times ot `occurrence vary in accordance with the signal modulation to variable width pulses whose duration or width correspond to the signal modulation.
The variable width pulses from the output of the trigger circuit 23, 24 are supplied to a low pass filter 34 which removes all Vhigh frequency components and passes the audio signal to the audio ampliiler tube 21.
From the foregoing, receiving system has amplined the weak radio frequency pulses, converted them to D. C. pulses (video) and then supplied these pulses to the receiving multiplex at a suitable ampliiier level. The receiving multiplex system regenerates the synchronizing period (100 microseconds) directly from the incoming signal, and with it separates the channel pulses in the same order that they were originally generated. vThe separated pulses` are then demodulated to give eight voice frequency outputs.
v A description will now be given of Figs. 3a and 3b which illustrate the circuit details of the system of the invention.v
The synchronizing separator comprises a triode tube I normally .biased to out oil and also tube 2 which is coupled to the output of triode I through a di'erentiator circuit. Tube I acts as alimiter. The video pulses (curve B) from the radio receiver are applied to the grid of triode I. Tube lv Lis biased to be normally nonconducting and conducts only during the pres- Y ence ofa pulse, or, putting lit in other words, it
The arrangement of the channel selector and applied to the grid of tube 2.
conducts only during the time of the individual pulses, whether channel or synchronizing pulses. Tube I acts as a limiter and its output comprises spaced pulses whose polarity are reversed relative-tothe input pulses. These reversed polarity pulses in the output of tube I are differentiated C.) Tube 2 is also normally non-conducting;
and is so biased that only the peaked positive-` going impulse produced from the trailing edge.'
of the synchronizing pulse will cause it toconduct. This is because the peaked impulses produced from the synchronizing pulses are of larger amplltudethan the peaked impulses produced from the channel pulses, duev to the factthat the synchronizing pulse is of longer duration than the channel pulses. u
The discharge pulse generator comprises tubes 3,- 4 and 5. The output from the synchronizing separator, taken lfrom the cathode of tube 2, is a peaked pulse in the positive direction which gradually diminishes over about 33 microseconds, and this gradual diminution of the pulse is caused by the discharge time of the capacity to ground through the high cathode resistor 40 ofk vtube 2 and the grid of the following tube 3- in the dischargepulse generator. (Note curve D.)
The discharge pulse from the discharge pulse generator is supplied both to the phasing trigger and to the step wave generator. The'phasing trigger is a self-restoring trigger circuit having one degree of electrical stability and comprises tubes 6 and 1. vIn eect, this phasing trigger is nothing more or less than a delay circuit it will be seen that the (Note curve for delaying the pulses passed thereto by a predetermined amount. Normally. tube 6 is nonconductive and tube 1 conductive. When this trigger circuit is iired. it remains in its active l state for a time detennined by the time constant of the circuit. The amount of delay is adjusted by means of a tap on the anode resistor of tube 1. The positive pulse from the cathode of tube I of the pulse generator is applied to the grid of tube 6 of the phasing trigger and tires the trigger circuit to its active state. Output from the phasing trigger is taken from the common cathode circuit and xs primarily a negative pulse whose trailing edge has an overshoot or positive peak, so to speak, which is utilized to excite the A90 kilocycle exciter 8 (note curve J).
The 90 kilocycle exciter comprises a vacuum tube 8 having in its anode a parallel tuned circuit I' whose resonant frequency is 90 kilocycles. 'I'his tuned circuit is loosely coupled to the anode of the exciter tube. The exciter tube 8 has a selfbias which adjusts itself so that it passes current only on the overshoot or peaks of the waves supplied to it by the phasing trigger. Note curve J. This overshoot occurs once each frame; or, putting it in other words, once for each synchronizing pulse but not necessarily at the synchronizing pulse time. When the exciter tube passes current, it supplies a driving pulse or kick (curve K) to the 90 kilocycle tuned circuit 6'. `This driving pulse or kick sets the tuned circuit into oscillations at a 90 kilocycle rate. These oscillations are of sine wave form and tend to decay slightly. In this particular case, the driving pulses from the 90 kilocycle exciter occur at intervals of 100 microseconds corresponding to a rate of 10,000 per second. Thus, one driving pulse is supplied to the tuned circuit for every nine cycles of sine wave oscillation generated in the tuned circuit. This is shown in curve L.
The portion X of the curve J is adjustable by adjustmentv of the resistor I8 of the phasing trigger.
The output of the tuned circuit l' is passed to the grid of vacuum tube 9 of the 90 kilocycle limiter. This tube passes only the positive halves cycle exciter; and the decaying amplitude of the pulse of curve M is caused by the inherent damping of the 90 kilocycle tuned circuit 8'. Thus, this 90 kilocycle tuned circuit 8' is maintained in oscillation by its exciting pulse.
Output from the 90 kc. limiter is taken from the anode circuit of tube I0 via lead |05 and this Voutput of curve N is passed onto the grid of vacuum tube I2 of the step wave generator as a series of recurring positive pulses. The step wave 4generator is of the form described in my copending applicationSerial No. 629,169 tiled November 16, 1945 wherein the legend positive input pulse" in the drawing thereof, corresponds to the pulses passed by the 90 kilocycle limiter 9, Il to the step wave generator. The legend synchronizing pulses" in my copending application Serial No. 629,169 corresponds tothe discharge pulse passed to the step wave generator directly from the ihode of tube 5 of the pulse generator over lead The coupling vacuum tube I3 corresponds to the cathode follower tube G of my copending application Serial No. 629,169. Step wave output is taken from the cathode oi this coupling tube and supplied via lead |02 to the channel selector circuits 2I, 2|', 2|".etc., of the diilerent channel units shown in Fig. 1. This step wave output supplied to the channel units is curve P. The channel units also have supplied thereto the video pulses from the radio receiver over lead IIII.
In my step -wave generator, the anodes of vacuum tubes Il, I2 and `|3 are connected to a common source of anode polarizing potential +290 volts. Triode tube I2 is biased by the resistorcondenser combination 4| in its cathode circuit so as to be normally non-conducting. The grid of triode I2 is connected through a resistor 42 and a coupling condenser 43 to lead |05 which supplies D. C. input pulses of positive polarity (curve N) from the output of tube II) of the 90 c. c. limiter. Each of thse input pulses (curve N) is of suill- `cient magnitude to overcome the cut-off bias of tube I2 and cause it to conduct for the duratio of the applied pulse.
A storage or step condenser Il is connected between ground and the circuit combination 4|, as a result of which an incremental charge of voltage is built up on this condenser whenever tube I2 conducts. A step wave voltage is built up across condenser M, and this step wave voltage has a plurality of steps -of increasing amplitude corresponding in. number to a desired number of input pulses (curve P).
Tube II is a normally non-conductive vacuum tube which, when it conducts, serves to restore coupling condenser I3 to its original condition after each input pulse. The cathode of tube II is connected to the grid of tube I2, while the grid of tube II is connected via lead 46 to the circuit combination 4 I.
Tubes a, b and c are normally non-conductive and become conductive simultaneously. The grids .of these tubes are connected together and their cathodes are also connected together and to ground. The space path of tube c is effectively across step condenser 44, and when this tube con- \ducts, it forms a low impedance discharge path cross condenser M. Tube b, when it conducts, insures the quick discharge oi the load capacity connected to the cathode of tube I3. Tube a serves to prevent tube I2 from conducting during the discharge of step condenser M. In Fig. 1, the channel selectors 2|, 2 I, 2|" are differently self-biased, and each channel selector is normally biased well beyond the current cut-off condition.
The channel selector is substantially like that shown in Houghton copending application Serial No. 608,957, supra, except for the fact that in the anode circuit, a coil 20 is used instead of a resistor. This coil 30, Fig. 3b is a differentiating coil and its purpose is to provide a much shorter pulse than that provided by the output of the channel selector described in the Houghton copending application. The channel selectors are differently biased to operate on successive risers of the step wave output (curve P) from the step wave generator II, I2. Each step or rise in the step wave voltage appearing in lead |02 is great enough to insure that during its occurrence the attacco current of the corresponding biased .channel .selector shall be driven rapidly from beyond the current cut-otr condition toa zero bias value. Once a channel selector. which is normally cutoif, passes current, (it responds to the increase in voltage on the particular step rise), it will" continue to pass current until the completion of the step wave voltage. The dierentiated short pulse output from the channel selector 2l' is in the negative direction, as shown in curve Q, -for example, (corresponding to channel 4) and is passed on to a self-restoring trigger circuit com` prising vacuum tubes 23 and 24.
f' low pass filter removes all high frequency corn-V The video pulses from the output of the radio non-conductive. These video pulses are of posi-- tive polarity and are not of themselves of sufli cient amplitude to make the gate 22 conduct.l However, when the trigger circuit 23, 24 is red and is in its active state, there is supplied to the grid of the gate 22 over lead 3| a positive vvoltage pulse from the common cathode circuit of the trigger circuit. This positive voltage pulse from the trigger circuitl applied to the grid is of sutil-1 cient magnitude to reduce lthe cut-oil bias on the tube 22 to an extent such that if at this time a video signal pulse of positive polarity is also ap-` plied to the grid via lead lili, the resulting volt; age from both the video signal pulse and the` trigger pulse are sufcient to overcome the bias on the gate 22 and cause it to conduct. It will` thus be seen that only in the simultaneous presence of both the video signal pulses and a positivev pulse from the trigger circuit will the'l gate 22 of any one chanel pass current. Whenl the gate 22 passes current, the voltage on its anode will drop and cause the eil'ective .application via lead 32 of a negative pulse to the anode of tube 23 of the trigger circuit of a magnitude suillcient to restore the trigger circuit to normal. Output s s.. from the trigger circuit in the form oi a variable` width pulse is taken from the anode of tube 24.'
via lead 33 and fed to a low pass filter 34. This ponents and passes the audio signal to the audio amplifier tube 21. i A
Curve R illustrates the voltage wave forxn ap pearing on the grid of gate 22. The short sharp pulses correspond to the signal pulses and these short sharp pulses are not suiiicient of themselves to'overcome the cut-oi! bias of the gate. The large. longer duration pulse corresponds to. the voltage occurring on the grid of 22 due to the simultaneous application of both a video signal pulse and a positive pulse from the trigger cir-` cuit, and the peak of this larger amplitude longer duration pulse has a magnitude suilicient to overcome the' cut-oi! bias on the gate 22.
Curve S shows the voltage variation at the common cathode of the trigger circuit 23, 24. The fixed edge is determined by the firing pulse for the trigger circuit 23, V24 supplied from ,the channel selector, while the trailing or modulated edge isdetermined by the -restoring pulse supplied ib the gate 22. i
after passing through the low pass. lter, appear on the grid of tube 25 in the form vshown in curve T.
In 'the absence of signal modulation for this particular channel, the wave vform at the grid of tube 25 has the form of the solid line of curve T. Pulse rectifier tube 25 is supplied with a floating ilxed bias from the rectier 26. This bias is adjusted to a value such that the pulse of the solid line of curve T causes conduction near the peak of this pulse. This conduction current ilows through resistance 36 in the cathode of tube 23' to a source of negative bias -10 volts. The con'- duction current through resistor 35, is suillcient to maintain the 4cathode of tube 25 at a potential in the neighborhood of +5 volts with respect to ground. i v l This bias is supplied to the grid of audio ampliiler tube 21 through a. lowlpass lter comprising resistances 31, 38` and capacitor 39. This condition causes audio amplier tube 21 to conduct in normal fashion as an audio amplier.
In the presence of modulation. the pulses applied to the grid of tube 25 are shown in their extreme modulated positions by the dotted lines of curves T. It should be kept in mind that the positive going pulse .appearing at the anode of trigger tube 23 has a variable width correspond-l ing with the channel modulation. This variable width pulse undergoes a wave form distortion upon passing the lowpass lter between the anode of tube 23 and thegrid of tube 2,5. This distortion is such that a wide pulseis passed with a small amplitude, as shown in curve T. It will be observed that tube 25 conducts only on pulsesy greater than a certain amplitude near the peak I tion. Serial No. 608,957 supra. the ringing is nc-v eomplished by advancing a channel pulse to itl ananas extreme position, where it remains for the duration of a' ring. This ringing condition produces a narrow pulse at the anode of trigger tube 23 and this pulse, after passing the low pass illter to the grid oi tube 28, isof such low amplitude that it cannot overcome the ilxed bias on tube hence tubey 25 remains completely non-conducting. Under thiscondition, the voltage at the cathode to tube 2l is maintained at a value closeV to minus 10y volts with respect to ground. 'I'his condition provides this same negative bias at the grid of audio ampliiler tube 21 causing it to be essentially at cut-oli. In the plate circuit of tube 21 is connected, along with the audio output transformer, a ringing relay which is kept closed by the normal plate current of thisl tube. When this tube is cut 'oil'. the ringing relay opens and causes a twenty cycle ringing channel generator to be started and switched on to the outgoing line.
What is claimed is:
l. A pulse multiplex receiving system for receiving from a remote transmitting system a plurality of equal duration spaced channel pulses followed by a synchronizing pulse, comprising a receiver for producing spaced video pulses which occur at time intervals corresponding to the received pulses, a separator circuit for separating the video pulse representative of the synchronizing pulse from the channel pulses, a discharge pulse generator coupled to said separator circuit for producing a pulse for each synchronizing video pulse supplied thereto, a phasing trigger circuit coupled to the output of said discharge pulse generator, said phasing trigger circuit having means for producing a peak voltage which occurs an adjustable interval of time after the pulse supplied thereto by saiddischarge pulse,
generator, a sine wave generator coupled to the output of said phasing trigger circuit and responsive to the peak voltage passed thereto, a limiter in the output of said sine wave generator, a stepA wave generator coupled to the output of said limiter and responsive to the limited waves for producing a step voltage wave having a desired number of steps or risers, a connection from the output of said discharge pulse generator to said step wave generator for controlling the termination of the step-voltage wave produced by said step wave generator, a plurality of channel units coupled to the output of said step wave generator, a connection from said channel units to the output of said receiver to obtain therefrom video channel pulses, said channel units having individual selector circuits which are differently biased to become conductive on diiierent risers of the step voltage wave, and said channel units having apparatus for converting the video channel pulses to variable width pulses.
2. In a pulse multiplex system wherein a plurality of equal duration spaced channel pulses and a single longer duration synchronizing pulse are transmitted for each frame or cycle of operations and wherein the occurrence time of each channel pulse is variable over a range by the signal modulation for that particular channel, a receiving system including apparatus for producing D. C. pulses representative of said channel and synchronizing pulses, a circuit responsive only to the D. C. synchronizing pulse for producing another pulse. a discharge pulse generator coupled to said last circuit for producing a pulse in response to each pulse supplied to said generator by said last circuit, means for producing a voltage wave of adjustable occurrence time from the pulse produced by said pulse generator, a shock-excited sine wave generator coupled to said means for producing a number of sine waves corresponding in number to the received pulses tor each frame or cycle oi operations, a step wave generator coupled to the output of said shockexcited sine wave generator for producing a step voltage wave having a plurality of steps or risers corresponding in lnumber to the number ofreceived pulses for each trame or cycle of operations. a connection from the output of said discharge pulse generator to said step wave generator for supplying a discharge pulse to said step wave generator, a plurality oi' channel units coupled to the output of said step wave generator, said channel units having individual circuits which are differently biased to become responsive on diiferent risers of the step voltage wave. and means for supplying D. C. channel pulses from said apparatus to said channel units.
3. In a pulse multiplex system wherein a plurality of equal duration spaced channel pulses and a single longer duration synchronizing pulse are transmitted for each frame or cycle of operations and wherein the occurrence time of each channel pulse is variable over a range by the signal modulation for that particular channel, a receiving system including apparatus for producing D. C. pulses representative of said channel and synchronizing pulses, a discharge pulse generator normally biased to cut-oi! and responsive to said synchronizing pulses to thereby produce other pulses, a shock excited oscillator'norxnally biased to cut-on and coupled to said pulse generator and responsive to a pulse produced by said generator for in turn producing a plurality of equally spaced waves corresponding in number to the number oi' channel and synchronizing pulses in each frame or cycle oi operations, a step wave generator coupled to the output of said shock excited oscillator i'or producing a step voltage wave having a plurality oi' steps or risers corresponding in number to the number of received waves for each frame or cycle of operations, a plurality of individual channel circuits coupled to the output of said step wave generator and a con-- nection for supplying D. C. channel pulses to said channel circuits, said channel circuits being so constructed and arranged as to become responsive on different' risers oi' the step voltage wave, and having apparatus for converting the D. C.
- channel pulses of varying occurrence time to variable width pulses.
4. In a pulse multiplex system wherein a plurality of equal duration spaced channel pulses and a synchronizing pulse are transmitted for each liframe or cycle of operations and wherein the occurrence time of each channel pulse is variable over a range by the signal modulation for that particular channel, a receiving system including apparatus for producing D. C. pulses representative of said channel and synchronizing pulses, normally non-conductive means responsive only to the D. C. synchronizing pulse for producing a plurality of equally spaced waves corresponding in number to the number of channel and synchronizing pulses in each frame or cycle of operations, said means including a shock excited damped tuned circuit and a circuit preceding said shock excited damped tuned circuit for varying the .phasing or time oi.' initiation of the equally spaced waves produced by said tuned circuit, a step wave generator coupled to said means for producing a step voltage wave having a plurality oi steps or risers corresponding in number f ll to the number-o1 received waves for eachframe or cycle of operations, a plurality of individual channel circuits coupled to the output of said step wavek generatorand a connection forv supplying D. C. channel pulses'to said channel circuits, said channel circuits being so constructed i and arranged as to become responsive on diilerent risers o! the step voltage wave, and having apparatus'for converting the D. C. channel pulses of varying Ioccurrence time to variable width pulses.
5. In a pulse multiplex system wherein a plurality of equal duration spaced channel pulses and a synchronizing pulse are transmitted for115 each frame or cycle of `operations and wherein the occurrence time of each channel pulse is va-` riable over a range -by the signal modulation for vidual channels, and causing different channels to become responsive at'difrerent times corre-3 sponding `to the occurrence time of the risers of said step voltage wave.
6. In a pulse multiplex system wherein a plu-3 rality of equal duration spaced channel pulses and a synchronizing pulse are transmitted. for each frame or cycle of operations and wherein the occurrence time of each channel pulse is va` riable over a range by the signal modulation for that particular channel, the method of operation which includes receiving the transmitted pulses, producing from only thereceived synchronizing pulse a plurality of equally spaced waves corresponding in number to the number of pulses received during each frame or cycle of operations and commencing at an adjustable time after the receipt of said synchronizing pulse, producing from said equally spaced waves a step voltage wave having a plurality of steps or risers corre-` in number to the number ofi sponding in number to the'number of ceived during each frame or'cycle of operations, feeding the received pulses to a plurality of indie A vidual channels, causing different channels to become responsive at diierent times correspondingA to the occurrence time of the risers of said step voltage wave, and converting the received pulses of variable occurrence time fed into saidy channelstovariable width pulses.
7. In a pulse multiplex systemfproducing a plu.-`
rality of spaced channel pulses and a synchroniz-f ing pulse for each frame or cycle of operations, a
receiving system therefor comprising a circuitfor separating the synchronizing pulse4 from .the channel pulses'.A an electron. dischargeV device biased to the current cut-oi! condition and a circuit therefor for producing sine waves.,l and means located between said device and: said separator circuit and responsive only to the separated syn-v chronizing pulse in the output oi-said separator circuit for producing a pulse -which overcomes said cut-of! bias to thereby cause said device and associated circuit to produce a plurality of :sine waves corresponding in number to the number of received pulses for each frame or cycle of operations, said means including self-restoring trigger circuit having only one degree of electrical stability for varying the phasing or time of'initiation of said plurality of waves, and a` stepwave generator coupled to and responsive to the output of said means for producing a step voltage wave having a plurality of steps or risers corresponding in number to the pulses in each `frame. A
' JAMES R. DAY.l
y REFERENCES orrEn The following references are of record in the ille of this patent:
UNITED STATES PATENTS Number Name Date 2,262,838 Deloraine NOV. 18, 1941 2,403,210 Butement .July 2, 1946 2,413,440 Farrington Dec. v31, `1946 2,416,330r4 Lubin Feb. 25, 1947 2,438,904 Rosa Apr. 6, 1948 2,442,770 Kenyon June 8, 1948 2,443,619
Hopper June 22, 1948 number of received
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US673746A US2469066A (en) | 1946-06-01 | 1946-06-01 | Pulse multiplex receiver |
GB13686/47A GB633730A (en) | 1946-06-01 | 1947-05-21 | Pulse multiplex communication system |
FR947266D FR947266A (en) | 1946-06-01 | 1947-05-28 | Pulsating multiplex communication system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US673746A US2469066A (en) | 1946-06-01 | 1946-06-01 | Pulse multiplex receiver |
Publications (1)
Publication Number | Publication Date |
---|---|
US2469066A true US2469066A (en) | 1949-05-03 |
Family
ID=24703967
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US673746A Expired - Lifetime US2469066A (en) | 1946-06-01 | 1946-06-01 | Pulse multiplex receiver |
Country Status (3)
Country | Link |
---|---|
US (1) | US2469066A (en) |
FR (1) | FR947266A (en) |
GB (1) | GB633730A (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2664509A (en) * | 1948-01-09 | 1953-12-29 | Rca Corp | Pulse multiplex communication system |
US2712064A (en) * | 1951-01-06 | 1955-06-28 | Gen Precision Lab Inc | Test pattern generator |
US2961611A (en) * | 1957-01-17 | 1960-11-22 | Epsco Inc | Frequency discriminator |
US3087992A (en) * | 1959-03-10 | 1963-04-30 | Arnoux Corp | Telemetering decommutation system |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2262838A (en) * | 1937-11-19 | 1941-11-18 | Int Standard Electric Corp | Electric signaling system |
US2403210A (en) * | 1942-12-04 | 1946-07-02 | Butement William Alan Stewart | Multiplex pulse modulation system |
US2413440A (en) * | 1942-05-15 | 1946-12-31 | Hazeltine Research Inc | Electronic switch |
US2416330A (en) * | 1944-08-07 | 1947-02-25 | Standard Telephones Cables Ltd | Multichannel receiving system |
US2438904A (en) * | 1942-11-23 | 1948-04-06 | Standard Telephones Cables Ltd | Timing system |
US2442770A (en) * | 1943-04-20 | 1948-06-08 | Sperry Corp | Pulse generator |
US2443619A (en) * | 1945-02-08 | 1948-06-22 | Bell Telephone Labor Inc | Pulse generator of the shockexcited type |
-
1946
- 1946-06-01 US US673746A patent/US2469066A/en not_active Expired - Lifetime
-
1947
- 1947-05-21 GB GB13686/47A patent/GB633730A/en not_active Expired
- 1947-05-28 FR FR947266D patent/FR947266A/en not_active Expired
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2262838A (en) * | 1937-11-19 | 1941-11-18 | Int Standard Electric Corp | Electric signaling system |
US2413440A (en) * | 1942-05-15 | 1946-12-31 | Hazeltine Research Inc | Electronic switch |
US2438904A (en) * | 1942-11-23 | 1948-04-06 | Standard Telephones Cables Ltd | Timing system |
US2403210A (en) * | 1942-12-04 | 1946-07-02 | Butement William Alan Stewart | Multiplex pulse modulation system |
US2442770A (en) * | 1943-04-20 | 1948-06-08 | Sperry Corp | Pulse generator |
US2416330A (en) * | 1944-08-07 | 1947-02-25 | Standard Telephones Cables Ltd | Multichannel receiving system |
US2443619A (en) * | 1945-02-08 | 1948-06-22 | Bell Telephone Labor Inc | Pulse generator of the shockexcited type |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2664509A (en) * | 1948-01-09 | 1953-12-29 | Rca Corp | Pulse multiplex communication system |
US2712064A (en) * | 1951-01-06 | 1955-06-28 | Gen Precision Lab Inc | Test pattern generator |
US2961611A (en) * | 1957-01-17 | 1960-11-22 | Epsco Inc | Frequency discriminator |
US3087992A (en) * | 1959-03-10 | 1963-04-30 | Arnoux Corp | Telemetering decommutation system |
Also Published As
Publication number | Publication date |
---|---|
GB633730A (en) | 1949-12-19 |
FR947266A (en) | 1949-06-28 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US2744960A (en) | Time-multiplex pulse-code modulation signal transmission system | |
US2546972A (en) | Television synchronizing system | |
US2359447A (en) | Electrical circuit | |
US2403210A (en) | Multiplex pulse modulation system | |
US2478919A (en) | Pulse type multiplex communication system | |
US3144515A (en) | Synchronization system in timedivision code transmission | |
US2497411A (en) | Pulse transmission system | |
US2513910A (en) | Multiplex telegraph system | |
US2550821A (en) | Combined television and sound system | |
US2447233A (en) | Pulse time modulation multiplex receiver | |
US2462111A (en) | Multichannel pulse distributor system | |
US2430139A (en) | Pulse number modulation system | |
US2487682A (en) | Synchronizing system | |
US2540167A (en) | Synchronizing system | |
US2231792A (en) | Synchronizing system and method | |
US2469066A (en) | Pulse multiplex receiver | |
US2165770A (en) | Electrical control apparatus | |
US2614210A (en) | Pulsed radio signaling | |
US2605360A (en) | Time division multiplex system utilizing a step-wave generator in the distributor circuit | |
US2465925A (en) | Radio control system | |
US2510987A (en) | Multiplex time modulated electrical pulse demodulation system | |
US2480582A (en) | Synchronizing pulse gating system | |
US2419546A (en) | Delay circuit | |
US2495168A (en) | Channel unit for multiplex systems | |
US2529564A (en) | Pulse multiplex receiving system |