NO780319L - DEVICE FOR THEFT SURVEY OVER TELEPHONE LINE - Google Patents

Description

System for remote monitoring and remote control over an automatic telephone network.

The invention relates to a system for remote monitoring and remote control over an automatic telephone network, between at least two subscriber devices.

The purpose of the invention is on this basis, without the risk of unwanted intervention by unauthorized persons, to provide remote control of a subscriber and automatic alarm transmission from this to another subscriber, e.g. sending out a burglar alarm or transferring a conversation with a visitor via a door phone at the subscriber's front door.

This is achieved according to the invention by a code signal being sent from the subscriber who wants monitoring and remote control at another subscriber using a number of sequence circuits, and then a specific monitoring signal or remote control signal is sent to the other subscriber so that the device acts as a monitor and remote control;

I) the device produces a certain number of pulses and has , some input terminals and one output terminal and the pulses that are sent into two "input terminals can produce different numbers of output pulses, because the individual input terminals are assigned a specific number of pulses and the number of pulses corresponds to the number of sequence circuits, and the selected remote control units are energized, and when the pulse signal for the relevant remote control unit or the specific monitoring signal is sent, an output signal will be sent from the output terminals of the remote control unit or from the monitor,

II) after sending out the fixed number of pulses, these can be stored in the caller's device and can thus be used as a data source for automatic number selection for controlling the electronic switch and can also be transformed into a sine signal and sent over the telephone line to the other subscriber,

III) comprising two storage devices. When the second subscriber is monitored by the first subscriber, telephone number data for the first subscriber will be stored in the storage device of group I and sent to subscriber C by subscriber B when subscriber C calls subscriber B and this data is stored in a storage device of group II at subscriber C for subsequent automatic calls from subscriber C,

IV) a device to prevent automatic connection and before subscriber B calls back for remote control or monitoring, a switch must be operated to give a control terminal high potential and after the call signal has appeared and disappeared while the connection is established, an output signal will be supplied a delay circuit, logic calculation is made with the output signal and control terminal'^ is given a high potential, so that a series of pulses are sent out quickly and the automatic connection is stopped by applying these pulses and leaves subscriber B waiting for remote control or monitoring,

V) automatic disconnection using a filter with a large time constant, high potential is provided by the filter because a series of pulse signals is emitted from the second subscriber, and applied to the setting terminal in a delay circuit and high potential from the filter is reduced to low potential, because the pulse train has disappeared and then the delay circuit emits a high potential and thereby the telephone line will be disconnected and calls will be made again,

VI) - a device for connecting an internal telephone to the telephone line when a visitor operates a switch at the entrance door of subscriber B, whose device calls the subscriber by automatically selecting subscriber A's number which is stored with subscriber B, and thereby a conversation between the visitor at subscriber B and subscriber A directly,

VII) if a break-in occurs at subscriber B, calls are made by automatic dialing from subscriber B to subscriber A using the stored telephone number. If subscriber A's telephone is busy, the telephone station sends a certain short signal that will cause continued calls until connection is created,

VIII) a device for identifying the theft alarm when a call signal is sent automatically to subscriber A from subscriber

B, where a burglary has been committed, an investigation signal is sent from subscriber A, a circuit at B is energized, so that a pulse signal is sent to subscriber A from subscriber B that follows a set pulse number or number sequence which, after being counted, indicates where a burglary has been committed.

Further features of the invention will appear from claims 2-14.

An embodiment of the invention will be explained in more detail below with reference to the drawings. Fig. 1 shows a circuit core for a period counter with thirteen digits. Fig. 2 shows a connection core for the circuits that deliver a fixed number of pulses. Fig. 3 shows a connection core for the circuits with a pulse counter (including the device for identifying the burglar alarm). Fig. 4 shows a connection core for the sequence circuits. Fig. 5 shows a connection core for remote control circuit selection. Fig. 6 shows a connection core for storage device and decoder. Fig. 7 shows a connection core for the monitoring circuits. Fig. 8 shows a connection core for the telephone connection. Fig. 9 shows a connection core for the delay circuit. Fig. 10 shows a block diagram of the inventive device. Fig. 1 shows a period counter with 13 digits, containing a normal decoding matrix and four flip-flop circuits TFi (i=0,1,2,3). Fig. 2 shows a circuit which produces a fixed number of pulses when operating switches KO, Kl,... K9, KC and KR, one at a time in turn on terminal CP, as high potential will occur one, two, . .. ten, eleven, and twelve times one and one in turn, i.e. one, two, ... ten, eleven and twelve pulses. A delay circuit SR-1 (Fig. 9)) which when terminal R has a high potential gives terminal 0 a high potential and terminal 1 a low potential,

but when terminal S gets high potential, terminal 0 does not change to high potential and terminal 1 to low potential right away, but only when high potential on terminal S is removed and then terminals 0 and 1 will change potential. If terminal S is not pulsed as a result of a high potential on terminal R (when no pulse is supplied from the OR gate circuit 02, the transistor Ul is blocked and a high potential occurs on the NOT gate circuit n2), so that terminal 0 gets a high potential and terminal 1 gets low potential. Even if terminal R is changed to low potential (during the first pulse on terminal S) terminal 0 will not be changed to high potential and terminal 1 to low potential, so that the first pulse cannot pass the AND gate circuit .a3 before the first pulse is removed and terminal 1 has become high potential, and the second or later pulse is able to pass the AND gate circuit.a3•

If pulses are delivered from terminal F3 and e.g. switch K3 is closed, the first pulse cannot pass the AND gate circuit a3•

Q1 is a period counter with 13 digits, as shown in fig. 1, and as reset supplies high potential from terminal 0

in the order 1, 2, ... after timing pulses have been applied one at a time.

When the switch K3 is operated, the first pulse is blocked by the AND gate circuit a3jbut the second, third, fourth and fifth pulses supplied to Ql will cause the high potential from terminal 0 to pass the NOT gate circuit nr3<:> and be fed back to the AND -the gate circuit a^ after changing to the opposite phase and immediately blocking this to prevent the passage of subsequent pulses.

Four pulses will therefore appear on terminal P. The same

will occur when operating other switches.

Fig. 3 shows a pulse counter and burglar alarm, where Jl transforms pulse signals into a sinusoid, J2 counts and indicates pulses^. SW1-SW4 are electronic switches, of which SW1 and SW2 are controlled high potential on terminal Hl, and SW3 and SW4 are controlled

of high potential on terminal H2. Terminals XI and Yl serve for connection to a telephone set. An incoming sinusoidal signal, when passing through a filter consisting of the capacitor C2 and parallel resistance, will be transformed into a pulse signal which is emitted from the AND gate circuits a6 and a7. Another filter consisting of the capacitor C3 with parallel resistance has a much larger time constant than the first filter, so that a pulse from the OR gate

the circuit 04 will give a low potential on the NOT gate circuit n4 and otherwise a high potential.

Porzinc circuit SR2 is similar to SRI in fig. 2 and in the normal state it changes the high potential of the NOT gate circuit n4 to the high potential of terminal 0 and the low potential of terminal 1, when a pulse train is emitted from the OR gate circuit 04. The first pulse will pass the AND gate circuit ag 2 and reset the counter Q2 and the second and subsequent pulses will pass the AND gate circuit ag to Q2. It is assumed that the OR gate circuit 04 emits i + 1 (i = 0 ,1, 2, ... 9 ) pulses continuously of times:n and when these have passed, a high potential will appear on the terminals 2-i (i=0, 1,2,...9). If the number of pulses from 04 is eleven or twelve and ceases after these, a high potential will appear on terminal RC1 or RS1 (fig. 4). Terminals CP and RP correspond to those in fig. 2 and leads to the delay circuit Q3 which has the same function as Q1 and Q2. In its normal state, the transistor Ul in fig. 2 blocked and high potential occurs on terminal RP and when a pulse occurs on terminal CP, an instantaneous low potential occurs on terminal RP.

When a pulse occurs at terminal CP, the first pulse will pass the AND gate circuit a^ 2 and reset the counters Q3 and J2, and the second and subsequent pulses may pass the AND gate circuit a^ to the counter Q3. If the number of pulses appearing on the terminal CP is eleven and the switch KC (Fig. 2) is operated, the terminal 10 of Q3 will emit a high potential and a pulse a_vgis from the OR gate circuit 04 will pass the AND gate circuit a-g and be counted and indicated in J2 .

Fig. 4 shows sequence circuits and pulses from AND gate

2 2 2 2

the circuit sl-^ q, a]_]_ja]_2°S a-,, is supplied one by one in turn to the period counter Q4 via the OR gate circuit 05 and terminal 4 in the counter Q4 emits a high potential which otherwise has a low potential.

The selectors VI, V2, V3 and V4 as in fig. 4 are in positions 4, 334 or 0 receives high potential from terminals 2-4, 2-3, 2-4 and 2-0 and emits this in turn via

2 2 2 2

The AND gate circuits a<->^,<a>^-^,<a>^2resp. a-^to terminal 4 in Q4.

The terminals 2-i (i = 0 ,1, 2 , ...9) are the same as in fig. 3, so that if terminal 4 in Q4 is to have a high potential, Q2 in fig. 3 pulses are applied four times and each of these pulses must

time have the sequence four, three, four resp. zero.

The number of pulses emitted from the OR gate circuit 04 each time must then have the following orderii five, four, five resp. one, and sine signals are sent four times on the telephone line in the same order, i.e. pulses must be sent four times from terminal A

on fig. 2 and 3 and each time in order five, four, five resp. one.

In order to deliver a high potential from terminal 4 in Q4, the switches on fig. 2 are operated in order K4, K3, K4 resp. KO which gives a start code 4340 and this code can be preset using the switches VI, V2, V3 and V4.

Before operating the starter switch KS in fig. 2, the switch KR must be operated in order for high potential to be supplied to terminal 11 in Q2 in fig. 3j and when terminal RS1 in fig. 4 has received a high potential, Q4 is reset and subsequent pulses from the AND gate circuit ag can be supplied to terminal CK1 via the AND gate circuit al4.

After operation of the start switch KS and Q4 is not reset, the subsequent pulses will not reach terminal S in the flip-flop circuit J4 and thus Q4 and terminals 0, 1, 2 and 3 in 2 2 2 this has a low potential and the AND gate circuits a- ^, a-^, a12°S aA is blocked. Each time the first pulse appears on the 0G gate circuit a2<g> in fig. 3, it is supplied to terminal RT in fig. 4. Between each pulse, the flip-flop circuit f 4—' is reset and a high potential appears on terminal 0.

If a pulse appears on terminal 0 immediately after the start signal, this will have a high potential, so that subsequent pulses from terminal CK1 via AND gate circuits al4 and al5 appear on terminal CK2. If high potential appears on terminal 0 in f4 regularly, terminal CT will also have high potential. The terminal CT is connected to the terminal CT in fig. 5, so that

the selected circuit for remote control in fig. 5 can be started. Terminals CK2, CK3, RS2 and B2 are connected to the corresponding terminals in fig. 5- Terminals Bl and B2 have a low potential as a result of the occurrence of a pulse and a high potential without the occurrence of a pulse, so that the condition in fig. 4 changes after each pulse, i.e. that terminals 2-0, 2-1,... 2-9 on fig. 4 has a high potential when pulsed at the output of the OR gate circuit 04 in fig. 3-

Fig. 5 shows a remote control selector for the individual remote control units that are connected to the output terminals ij (i,j=0,1,2,...9 ) • Output terminal 99 is only intended for a monitor. High potential on the output terminals comes via the associated AND gate circuits a^Q and a^i5 nif the inputs are connected to the output terminals from the counter Q5 or Q6.- If a high potential is to occur on the output terminals ij","', the respective output terminals in both Q5 and Q6 must have a high potential. When the OR gate circuit 04 in fig. 3 has not sent a start signal and thus the AND gate circuits al4, al5 and al6 in fig. 4 is not conductive, twelve pulses must be sent from 04 in order for a high potential to appear on the terminal: RS1 in fig. 4, and this high potential resets the counter Q4 of FIG. 4, the counters Q5 and Q6 and the flip-flop circuits TF4 and f5" in Fig. 5. After the start signal is sent out, a high potential appears on terminal CT and then subsequent pulses appear on terminal CK2 and everything is started again. Terminal B2 has a high potential and high potential therefore appears on terminal 1 of the flip-flop circuit TP4 when the first pulse appears on terminal CK2 and passes the AND gate circuit al8, so that the number of pulses determines which output terminal of the counter Q5 will signal. Terminal B2 is at low potential before the appearance of the first pulse and this changes to a high potential until the second pulse occurs. When the second pulse occurs at terminal CK2, terminal 0 of the flip-flop circuit TF4 becomes high potential, and the second pulse can pass through the AND gate circuit al9 and is fed to the counter Q6 which, in accordance with the number of counted pulses, emits an output signal on the respective output terminal. When terminal 99 gets a high potential that resets the flip-flop circuit f5

which, if it is to change state, must get high potential again from terminal 99 and terminal 0 will then get low potential and terminal 1 high potential.

High potential on terminal 1 in the flip-flop circuit,'f 5, when a pulse appears on terminal CK3, will cause this pulse to pass AND gate circuit" a23 and appear on terminal CK4. At the same time, high potential will pass AND- gate circuit a24 to terminal RC2, and at the moment a pulse appears or disappears, the NOT gate circuit n8 will emit a high or low potential and the high potential will pass the AND gate circuit a22 to terminal D. Counters Q5 and Q6 are common decimal dividers.

Fig. 6 shows a ■ memory and codes, where counters Q 7 and Q8 have 21 digits. Pi (i=l, 2,...20) are period counters with four-bit binary digits, W is a binary-decimal converter. When the clamp 99 in fig. 5 has a high potential and the first pulse appears on the OR gate circuit 04 in fig. 3 and the number of pulses is eleven and these eleven pulses disappear, terminal RC1 in fig. 3 has a high potential which is supplied to terminal RC1 in fig. 5, and can pass the AND gate circuit a24 to terminal RC2 in fig. 6 and the counters Q7 and Pi (i=1,2,...20) are reset. Before the first pulse appears on terminal D, this has a high potential because when there is no pulse, terminal B2 in fig. 5 high potential, so that low potential appears on the NOT gate circuit n8.

Terminal 1 in counter Q7 emits a high potential, so that a pulse signal from terminal CK4 will be supplied to counter Pl, and after the first pulse terminal 0 will have a low potential. When the second pulse occurs, terminal 0 will again have a high potential and terminal 2 emits a high potential, so that the second pulse is supplied to the counter P2. Each pulse will be supplied to the counters Pl, P2,... P20 in turn and the number of pulses will each time appear on the terminals a, b, c and d° in binary code, the number of nine four bits being sufficient, and the state is maintained as a kind of memory, which is locked and cannot later be changed when pulses are introduced, except by restarting from the beginning and selecting the monitor. What is sent after the preceding eleven pulses will be stored on terminals a, b, c and d in Pi (i=2,3,...20), i.e. in greater than 2, and exceeding pulses are not taken into account. When the 21st pulse occurs, the output 0 from the counter Q7 will have a high potential and the others a low potential.

If a high potential occurs at terminal G4, the counters Q8 and Q9 as well as the flip-flop circuit TF5 will be reset and the flip-flop circuit f6 "will be set and a high potential will appear at terminal 1. If a pulse occurs at terminal G4, a pulse at terminal G2 pass the AND gate circuit a49 and the high potential on terminal G4 vii disappear, while the pulse from a49 will cause the counters Q8 and Q9 as well as the flip-flop circuit TF5 to start working from the beginning. The pulse period from terminal .1 of the flip-flop circuit TF5 is applied to the AND- gate circuitsnea50 and a51 and the counter Q8, and this period is ten times the period of pulses from

the other input terminal of the counter Q9 and the AND gate circuit a513 so that during the period of occurrence of high potential, the AND gate

the circuit a51 emits ten pulses at a time.

During the period when counter Q8 is supplied with the first high potential, its terminal 1 will have high potential and the other terminals low potential. Therefore, the stored content in the counter P will be fed back to terminals a, b, c and d in the decoder W and will be changed to a decimal number, e.g. if the stored content in Pl is 0010, high potential will appear on terminal 2

in the decoder W and at that moment the AND gate circuit a51 will deliver ten pulses which will pass the AND gate circuit a^ 2 to the output terminal 1-2.

Of data stored in position j (j equal to or less than 19) in Pi (i = l,2,...20), j-1 are usable. When high potential occurs on terminal D j times, high potential will occur on terminal j which is supplied to an input terminal of AND gate circuit sl^' whose second input is connected to output terminal j-1 of counter Q8. During decoding of the stored content, a high potential will appear on the input terminal of the counter Q8 j-1 time and the AND gate circuit a.^ will emit a high potential to an input terminal of the AND gate circuit a48, whose other input is still at a low potential, until the high potential on the input terminal in the counter Q8 j-1 times disappears, and then the AND gate circuit a48 will emit a high potential.- This high potential will then via the OR gate circuit 06 reset the flip-flop circuit "f-6> whose terminal 1 will get low potential, so that a pulse from terminal G2 cannot pass the AND gate circuit a49- Even if position j in Pi (i=l,2,...20) stores data, during decoding only position j-1 will be decoded.

If there is data stored in all Pi (i = l,2,...20 ), high potential will appear on terminal 0 of counter Q7 and after 21. high potential will occur on terminal D before terminal 0 of counter Q7 is connected to an input in the AND gate circuit a2^3 whose second input is connected to the output terminal 20 of the counter Q8, so that high potential will appear on the AND gate circuit a^ after twenty times high potential on the input terminal of the counter Q8 during decoding so that data in all Pi are taken out.

Terminal 1-i (i=0,l,...9) is connected to corresponding terminals in fig. 2 during decoding and the extracted data is changed to pulses from the OR gate circuit 03-' The number of pulses excluding the number on terminal 1-0 is stored in Pi. The terminal 1-0 is the exception for the reason that no pulse is supplied to Pi because the OR gate circuit 04 in reality only emits one pulse and this happens when the switch KO in fig. 2. During dialing in the telephone set of digit 0, 10 pulses are produced, so that ten pulses are emitted from the OR gate circuit 03 while the pulse is emitted from terminal 1-0.

Data taken out during decoding of the stored data shall be stored on the opposite side in the group II storage device and this data is used for automatic number selection, while the opposite side receives ten pulses and in the binary counter in the group II storage device the output state is 1010 which does not

can be used in the decoder for conversion from binary to decimal form, because no output terminal can be adapted to 1010. The binary counter in group I storage device used for automatic number selection is designed as a period counter because when the tenth pulse is applied the output state will be back to 0000 , and that is desired.

Fig. 7 shows a monitor where the block J3 shown

in detail in fig. 8, has terminals X2, Y2. When no signal appears on these terminals, transistor U16 is blocked so that the potential at point Z1 is higher than at point Z2 and the base voltage on the transistor is higher than its collector voltage, so that transistor U17 is also blocked. Before the transistor U17 is blocked, there is no output signal at the point Z3 and the transistor Ul8 is blocked and a low potential occurs on the NOT gate circuit nl6, and a high potential will be emitted from the NOT gate circuit nl7 • When a large enough signal is applied to the terminals X2, Y2, the collector current saturates in the transistor Ul6, the potential at the point Zl is lowered to zero and the transistor U17 is blocked. When a weak signal is applied to terminals X2, Y27 becomes the collector current is not saturated and the potential at point Zl is lowered to lower than at point Z2. The transistor U17 becomes conductive and the output signal will appear at the point Z3. The collector current in the transistor Ul8 is therefore saturated and the collector voltage decreases to zero, so that a high potential is emitted from the NOT gate circuit nl7. Before the application of the weak signal on the terminals X2,Y2, the NOT gate circuit nl7 will have a low potential.

If a call is made in a telephone network from subscriber A to subscriber B, the call signal will be heard by subscriber A and when subscriber B answers, subscriber A will hear a short signal with a frequency equal to the frequency, approx. 400 Hz, for the call signal which is larger. These signals are applied to the terminals X2, Y2 at different times, and they can be identified as a result of the state of the output of the NOT gate circuit nl7, which emits a high potential for the call signal and a low potential for the answer signal. The delay circuits SR4 and SR5 in fig. 8 is similar to the delay circuits SRI, SR2 and SR3 and is shown in detail in FIG. 9. If the potential on terminal R is increased, a low potential will appear on terminal 1 immediately and a high potential will appear on terminal 0. If the potential on terminal S is increased after the high potential on it is removed, a high potential will appear on terminal 1 and the potential on terminal 0

will decrease. If a short signal is applied to the terminals X2, Y2, the NOT gate circuit nl6 will emit a high potential which appears on the terminal S of the delay circuit SR5 instantaneously and the potential on the terminal R decreases. In front of the filter consisting of the capacitor C6 and the parallel resistor, even if the short signal is not continuous and short before the short signal disappears, low potential will be held at terminal R and at this time low potential will still appear at terminal 1 of the delay circuit SR5, until high potential on terminal S disappears, and then the potential will rise again to high potential. While high potential disappears from the delay circuit SR5, high potential will be emitted from the AND gate circuit a57 which sets the flip-flop circuits fl5 and fl6, and then high potential will be emitted from the point Z5 and the output of the NOT gate circuit nl8 will change to low potential and the output of the AND -gate circuit a57 will quickly decrease to low potential. At this point, high potential is maintained at point Z5 until high potential appears on terminal S in the delay circuit SR5 again. Although high potential appears and disappears from the terminal S in the delay circuit SR5 the second time, high potential will not be emitted again from the point Z5. At the time of occurrence of the continuous short signal, low potential is maintained on the NOT gate circuit nl7 and the flip-flop circuit cannot be reset and the AND gate circuit a57 is not conducting, the short signal will not

occur again without the short signal disappearing and C6 being discharged. High potential will otherwise only occur once at point Z5.

No matter how many times the continuous short signal appears on the terminals X2, Y2, only one pulse will be emitted from the point Z5..1 meanwhile the high potential at the point Z5 disappears, the NOT gate circuit nl6 must emit a high potential, so that the NOT gate circuit nl9 emits low potential. Before the high potential at point Z5 disappears, the flip-flop circuit is set at high potential at terminal 1 of delay circuit SR4 and high potential is emitted from point Z6 and will disappear when the NOT gate circuit nl6 emits low potential and then the output of the NOT gate circuit nl9 will change to high potential. It also means that when short non-continuous signals appear on terminals X2, Y2, first a pulse is emitted from point Z5 and when this pulse disappears a second pulse will be emitted from point Z6 and then no more pulses will be emitted,

without the short signal disappearing for a while and the capacitor C6 is completely discharged and the short signals appear Pa hy, and "then" the points ~Z"5~and"Z6" will have a" low "potential after they have emitted high potential once at the beginning.

The block J4 in fig. 7 is shown in detail in fig. 8,

as framed by dashed lines L. When any number of pulses appear at point Z4, initially point Z5 will emit one pulse and when this has disappeared, point Z6 will emit one pulse and then both will be at low potential. J5 is a device for identifying a burglar alarm. The number and timing of the pulses can be determined as desired. In reality, it is a memory. The time can e.g. is selected to 3 and the number of first, second and third pulses can be selected to 8.5 or 9. When the potential on terminal RC1 is increased to a high potential, three pulses are emitted from the device J5 and the number of pulses is 8.5 resp. 9. J6 is a converter for pulse signals to sine signals which are emitted when the input has a high potential, otherwise no sine signal is emitted. J6 outputs non-continuous sine signals when J5 outputs non-continuous pulse signals. J7 is a pulse source that emits pulses continuously when desired. The setting of the time and number of pulses delivered by the device J5 can be done by remote control. One of the remote control units connected to the output terminals i,j (i,j=0,1,2,...9) can be set for burglar alarm identification.

Operation of the turning mechanism M coordinates the turnings m6, m7 and m8, which in the position gl with a solid line is the monitor position and in the position g2 is the normal state without a monitor. Switches ml and m2 are operated by a relay RL1 and act as when the handset is lifted from the telephone set. Terminals Al and A2 correspond to connection terminals for the ringing signal in the telephone set. If a call signal is given from the other subscriber, this will appear on the terminals ti, t2 and be supplied to the collector of the transistor UIO via the transformer T4. The terminals hl and h2 are used to connect the telephone set and the relay RL1 provides the operation as mentioned above and all signals from outside will appear on these terminals. Terminals el and e2 are used to connect a speaker device to the telephone device using the relay RL1 corresponding to lifting off the microphone and signals from the speaker device are sent out on terminals el,e2.

In the monitor position when the turning mechanism is in positions: gl, terminal 1 of the flip-flop circuit fl2 must have a low potential and the transistor UIO is blocked. If a signal appears on the terminals ti, t2, it is supplied to the base of the transistor U-9 via the transformer T4 and further passes the transformer T33 NOT gate circuit nl4 dg OR gate circuit 08 to terminal G4 for supply to the counters Q8 and Q9 as well as the flip-flop circuit TF5 in fig. 6, so that the pulse on terminal G2 can pass the AND gate circuit a495 and after the flip-flop circuit f6 is set, the flip-flop circuit f7 is set by high potential on its terminal 1 and high potential on terminal G3 will in fig. 7 make the transistor U7 conductive. This will cause relay RL1 to be energized and switches bl and b2 to be closed, which means the same as if the handset is lifted from the telephone set. The signal from terminals ti, t2. is a call signal which will cease when the handset is lifted. Although there is no other pulse on terminal G4, the switches b1, b2 remain closed as a result of the state of the flip-flop circuits f6 and f7 in FIG. 6, which serves as a kind of memory.

When the turning mechanism M is brought to the position g2 as shown by dashed lines, the terminal 1 of the flip-flop circuit fl2 must have a high potential. If the base resistance of the transistor UIO is chosen appropriately and terminal 1 of the flip-flop circuit fl2 has a high potential, the collector current will saturate instantly and the base voltage on the transistor U9 will be zero even with a signal on the terminals ti, t2, so that the NOT gate circuit nl4 still has low potential and the telephone set will work normally.

When the turning mechanism M is in the position where the monitor and signal appear on the terminals ti, t2, this must be a call signal, and there can then be two situations. Firstly, the subscriber can call the other subscriber. for remote control,

and secondly, the second subscriber can call the first subscriber.

SRO in fig. 2 is a delay circuit as shown in detail in FIG. 9- In the uncalled state, the terminal G7 will have a high potential, so that the delay circuit SRO and the flip-flop circuit fl are reset, and when the handset is lifted off it will have a low potential. If switches bl, b2 are closed by relay RL1, terminal G7 will still be at high potential even if the handset is lifted off, which is important. Terminals hl and h2 correspond to those in fig. 7 and serves to connect the microphone.

In the first situation, the first subscriber A must, after lifting the handset, operate the start switch KS in fig. 2 and thus terminal 1 in the flip-flop circuit fl gets a high potential and a pulse is emitted by the AND gate circuit aO and this passes the AND gate circuit a4. In the case of the other subscriber B, the object of the invention is connected to the telephone and a call signal appears on the terminals t1, t2 in fig. 7 and also on terminals hl, h2 in fig. 2 and 7 of the first subscriber A. With this call signal, subscriber A can cause the OR gate circuit nor 0 to send a high potential and thereby cause the NOT gate circuit nl4 of subscriber B to emit a high potential, so that the relay RL1 is energized and the call signal is stopped and the invention object at subscriber A will be brought to a low potential instantly so that terminal 1 in the delay circuit SRO will get a high potential and a pulse from terminal F3 will, when the device at subscriber A is in position for normal operation without a monitor, pass the AND gate circuits aO, and a4 and is emitted from the OR gate circuit 03, so that the terminal H2 gets a high potential, and the pulse can be sent from the AND gate circuit<2> to subscriber B. When subscriber A lifts the handset and operates the start switch KS and dials the number of subscriber B, the call signal appear and disappear and a pulse will be sent automatically to subscriber B, where the device is set as a monitor, and appear on terminals hl, h2 and after passing through the transformer T5 and is li rectified and filtered be supplied to the base of the transistor Ull which becomes conductive and the collector current is saturated and when the switch is closed by the relay, high potential will be emitted from the NOT gate circuit nl3 and the OR gate circuit norl will receive a high potential, because in monitor position the one input will in the OR gate circuits nor2 and nor3 have low potential and high potential is emitted from the NOT gate circuits nil and nl2. If nothing else happens, a high potential will appear on terminal G6 in fig. 6 and pass the OR gate circuit 06 and occur on terminal G1, as low potential will occur on terminal 1 of the flip-flop circuit f8 and the AND gate circuit nea52 and a53 are blocked and no pulse will occur on terminal G2. Decoding and storage will therefore not take place in fig. 6 and subscriber B is ready for remote control and work as a monitor.

If subscriber A did not operate the start switch KS, terminal 1 in the flip-flop circuit fl in fig. 2 have a low potential and the pulse is blocked by the AND gate circuit a4 when the connection with subscriber B is established and the transistor Ull at subscriber B is blocked and a low potential is emitted from the NOT gate circuit nl3 so that a low potential occurs at terminal G6 and a high potential will not occur on clamp Gl. High potential is emitted from the OR gate circuit 09 to the collector of the transistor Ull and high potential will appear on terminal 1 of the flip-flop circuit f8 too high potential is emitted from the OR gate circuit 09 because call signal appears on terminals ti, t2 and the NOT gate circuit nl4 emits high potential passing the OR gate circuit 010, so that high potential appears on terminal H2, but terminal H1 becomes low potential. A pulse produced by J7 will appear on the counter Q9 of fig. 6 and pass the AND gate circuits aSS, a52, the OR gate circuit 07 of Fig. 7 and the AND gate circuit a49 of Fig.

6 and start decoding and saving.

If a visitor e.g. operates the switch KA at the front door of subscriber B, a low potential will be emitted from the NOT gate circuit nil and the reversing mechanism M is in position gl, a high potential will be emitted from the OR gate circuit nor2 which then passes the OR gate circuits 09, 08 and acts on terminal G4, and high potential will also appear on terminal 1 of flip-flop circuit f8. Low potential emitted from the OR gate circuit nor. 1 causes the OR gate circuit nor 2 to emit high potential which appears on terminal H1 as a result of high potential from the NOT gate circuit n10. A pulse supplied by the source J7 and appearing on the terminal G2 will pass the AND gate circuit a55, the transistor Q10, the flip-flop circuit TF6, the AND gate circuit a53 and the OR gate circuit 07 and FIG. 6 will start decoding and saving. When a high potential occurs on terminal G4, the relay RL1 will be energized and the switches bl and b2 will be closed and automatic number selection will be started at subscriber B. If a door phone is placed at the entrance door and the switch KA is connected in parallel with a switch for this, the door phone will be connected and when the number selection has been carried out automatically, the visitor can talk to subscriber Ac' via the device at subscriber B. If subscriber A is busy, the visitor will hear a specific short signal and by operating a switch KP, the device is reset and the switch KA can be operated again later.

If alarm switches are provided at the front door

and at all windows of subscriber B and these are broken during a burglary, a pulse will be supplied to the device..J4 regardless of the number of pulses, and one pulse will be emitted from point Z5 first and then from point Z6 and the output will be kept at low potential. The pulse from point Z5 resets the devices J4 and J5 and the flip-flop circuit fli is reset by the pulse passing the OR gate circuit Oll, and then the pulse from point Z6 will set the flip-flop circuit fil via the OR gate circuit 012, and the relays RL1 and RL2 will be energized as a result of high potential on the flip-flop circuit fili, and the switches bl, b2 will be closed so that the same situation as lifting the microphone will occur. The relay RL2 operates the inverters m5 and m6 and the terminals hl, h2 are connected to the terminal x2, y2. On the other hand, the NOT gate circuit nl2 will emit a low potential as a result of the pulse from J4 at the point Z6 and a high potential from the OR gate circuit nor 3 is supplied to the input of the OR gate circuit nor 1, so that a high potential is also emitted from the OR gate circuit 08 to terminal G4 via the OR gate circuit 09. Then the flip-flop circuit will

fB be set and high potential will appear on its terminal 1. The output of the OR gate circuit nor 1 is low potential

because the input receives a high potential from the OR gate circuit nor 3 and a high potential is emitted from the NOT gate circuit nlO so that the terminal Hl, so that the pulse from J7 will appear on the terminal G2 via the AND gate circuit a553 the counter Q10, the flip-flop circuit TF6, AND- the gate circuit a53 and the OR gate circuit 07- At this time, high potential will appear on terminal G4 and the pulse will appear on terminal G2, so that fig. 6 will start decoding and storage and data that has been decoded and stored is taken out for number selection.

After the number selection, a short signal appears on the terminal hl, h2 of subscriber A and the terminals hl, h2 are connected to the terminals x2, y2 with the help of switches m5, m6 and the short signal is supplied to the device J3 shown in fig. 8, and a pulse is emitted first at point Z5 from J33 and then a pulse from point Z6 and the output is held at low potential and the entire circuit is first reset and then starts working again until a call signal appears on terminals hl, h2.

The object of the invention thus automatically dials if there is a break-in and the called subscriber lifts the handset and if he does not receive an answer he can operate the switch KC in fig. 2 and high potential will appear on terminal RC at the subscriber with a break-in, and this will cause J5 to emit a pulse which is transformed into a sine signal which is fed to terminals el, e.2 and transmitted to the other subscriber.

When subscriber A operates the switch KC, a high potential occurs on terminal 10 in counter Q3 in fig. 33because eleven pulses are emitted from the OR gate circuit 03. After an identity signal is sent from the place of intrusion, this signal will pass the AND gate circuit a^ 3 and indicated in J2 which shows the place of transmission.

At the time when the subscriber has visited the entrance door or a burglary has been committed, a high potential will appear on the terminal H1, so that a pulse from the source J7 passes the decimal counter Q10 and the flip-flop circuit TF6 to the terminal G2. This means that the frequency of the pulses from J7 is divided by 10 to match the pulses for automatic selection. The frequency of the pulse that appears on terminal G2 will be the same as the frequency of the source J7• When automatic selection occurs, only stored data is used which is sent directly to the other subscriber and the frequency is higher.

Fig. 10 serves to explain the entire system according to the invention.

When the microphone is lifted off and calls are made by dialing and the called subscriber is set as monitor, a low potential will appear on terminal G7, otherwise a high potential will appear on this, and data encoded and sent from the called subscriber will be stored in group In the storage device via the AND gate circuit a6.

If the handset is not lifted off and a high potential occurs on terminal G7, data sent from the other subscriber via the AND gate circuit a7 and the OR gate circuit 04 which is remotely controlled and monitored. If telephone calls are made from the other subscriber without any other specific function and the device is monitored, data from the group I storage device will be extracted quickly and sent over the telephone line via the AND port circuit a2 and the terminal H2 has a high potential.

If it is desired to store data there, the selector mechanism M in fig. 7 to position g2, and high potential will appear on terminals H5 and H3- In fig. 7, high potential will appear on terminal H2 because high potential on terminal H5 passes the OR gate circuit 010, so that data from the source VI will be supplied to the units V/IV and III via the 0G gate circuit ai and the OR gate circuit 04 and return to the telephone line via the AND gate circuit a^, but nothing happens because there is no dialing" done anywhere..

If a number is dialed and the other subscriber is to be set to monitoring and remote control, the selector mechanism M must be set to position g2, even if data from VI can. 12 .

pass the AND gate circuit a^, a^, but data cannot be entered into IV and III because start signal from outside and signal on the spot then have no effect.

When the other subscriber has a visit or there is a break-in and decoding and storage takes place, the terminal Hl will have a high potential, so that data from VI will pass the 0G gate circuit a^ and the NOT gate circuit n3, and interrupted switching on and off will is provided by switch SW5 and the basis for automatic number selection is reached.

When the second subscriber being monitored is called and

data from this is stored in group II storage device I,

the connection between the subscribers will be broken automatically, and the stored data will be transformed into pulses in VI and fed to switch SW5 via the AND gate circuit a^and automatic number selection will take place.

When this happens, data is received from the other

subscriber who is temporarily stored in group II storage device I. When data from the second subscriber is received, a high potential will occur on a certain terminal and this simultaneously disconnects the line connection and the first subscriber is ready for another number selection. How a particular control terminal is supplied with a high potential immediately after data has been transferred to the other subscriber occurs by using a larger time constant in the filter circuit, so that when a series of pulses are delivered from the filter circuit, a uniform high potential will appear which is supplied to terminal S in the delay circuit on fig. 9. When lifting the handset, terminal R in the delay circuit will have a low potential, i.e. immediately after the caller receives data from the called party and the output from the filter circuit is gradually reduced to low potential, a high potential will appear on terminal 1 in the delay circuit . High potential must be used to disconnect the external telephone line and make the device ready for new dialing, which also includes automatic dialing in accordance with data stored temporarily in group 2 storage device 1.

Claims (14)

1. System for remote monitoring and remote control over an automatic telephone network between at least two subscriber devices, characterized in that a code signal is sent from the subscriber who wants monitoring and remote control at another subscriber using a number of sequence circuits, and then a specific monitoring signal or remote control signal becomes sent to the other subscriber, so that the device acts as a monitor and remote control; (I) the device produces a specific number of pulses and has some input terminals and one output terminal and the pulses sent to two input terminals can produce a different number of output pulses because the individual input terminals are assigned a specific number of pulses and the pulse number corresponds to the order number of the sequence circuits , and those; ^selected remote control units are energized, and when the pulse signal for the relevant remote control unit or the specific monitoring signal is sent, an output signal will be sent from the output terminals of the remote control unit or from the monitor, (II) after sending out the fixed number of pulses, these can be stored in the caller's device and can thus be used as a data source for automatic number selection for controlling the electronic switch and can also be transformed into a sine signal and sent over the telephone line to the other subscriber, (III) comprising two storage devices. When the second subscriber is monitored by the first subscriber, telephone number data for the first subscriber will be stored in the storage device of group I and sent to subscriber C by subscriber B when subscriber C calls subscriber B and this data is stored in a storage device of group II at subscriber C for subsequent automatic calls from subscriber C, (IV) a device to prevent automatic connection and before subscriber B calls back for remote control or monitoring, a switch must be operated to give a control terminal high potential and after the call signal has appeared and disappeared while the connection is established, an output signal will be applied to a delay circuit, logic calculation is carried out with the output signal and the control terminal is given a high potential, so that a series of pulses are sent out quickly and the automatic connection is stopped by using these pulses and leaves subscriber B waiting for remote control or monitoring, (V) automatic cut-off using a filter with a large time constant, high potential is provided by the filter because a series of pulse signals is emitted from the second subscriber, and applied to the setting terminal in a delay circuit and high potential from the filter is reduced to low potential, because the pulse train has disappeared and then the delay circuit emits a high potential and thereby the telephone line will be disconnected and calls will be made again, (VI) a device for connecting an internal telephone to the telephone line when a visitor operates a switch at the entrance door of subscriber B, whose device calls the subscriber by automatically selecting subscriber A's number which is stored with subscriber B, and thereby a call can be made between the visitor of subscriber B and subscriber A directly, (VII) if a break-in occurs at subscriber B, calls are made by automatic dialing from subscriber B to subscriber A using the stored telephone number. If subscriber A's telephone set is busy, the telephone station sends a certain short signal which will cause continued calls until a connection is established, (VIII) a device for identifying the burglar alarm when a call signal is sent automatically to subscriber A from subscriber B where a burglary has been committed, an investigation signal is sent from subscriber A, a circuit at B is energized so that a pulse signal is sent to subscriber A from subscriber B which follows a set number of pulses or a sequence of numbers which, after being counted, indicates where a break-in has taken place. 2. System according to claim 1, characterized in that subscriber A first calls subscriber B and, after a connection has been established, a series of signals can be sent to subscriber B from subscriber A over the telephone line to provide remote control or monitoring. 3- System according to claim 1, characterized in that when a connection is established between subscriber A and B and remote control or monitoring is not provided, a pulse signal representing a different or the same number can be sent to subscriber B from subscriber A by following the set order as is stored in the sequence circuits of subscriber B, the "device selection circuits in the remote control" are energized by the output signal from the sequence circuits of subscriber B, after that. the next signal is sent to subscriber B, the units in remote control, including the monitoring unit, can be yelg~ed, and whoever does not know the order of the sequence circuits at subscriber B cannot interfere undesirably and disturb or stop monitoring or the remote control at subscriber B. 4. System according to claim 1, characterized in that the setting of the order of the sequence circuits takes place by means of a step selector and any changed connection takes place at their input terminals and step connectionsf." 5. System according to claim 1, characterized in that when subscriber B is monitored from subscriber A whose calling number data is stored at B and calls are made from subscriber C to subscriber B, calling number data for A stored at B1's storage device of group I will be sent quickly to subscriber C and this data will be stored in the storage device of group II at subscriber C and after completion of storage, the connection between subscriber B and C is broken and subscriber C calls subscriber A and connection is established directly automatically. 6. System according to claim 1, characterized by a device for preventing automatic telephone calls. When subscriber apparatus B is monitored and this subscriber calls his own apparatus from another remote control location for remonitoring, he first operates a number selection switch, and high potential appears on the energized control terminal, and when the connection is established and the call signal has appeared and disappeared, the delay circuit emits a high potential, logical calculation will be made with the high potential and high potential will appear on the control terminal, a gate circuit will become conductive and the pulse signal will be quickly sent to subscriber B, so that automatic telephone connection will be stopped and subscriber B will have remote control or renewed monitoring. 7. System according to claim 5, characterized in that when automatic connection occurs and telephone number data for subscriber A is sent to subscriber C from subscriber B, and this data is stored in the storage device of group II, the telephone line between subscribers B and C is automatically blocked, in that a larger time constant is used for the filter, so that when a number of data pulses are supplied to the filter, its output will emit a constant high potential which is supplied to the setting terminal in the delay circuit and when these pulses disappear, the output from the filter will again be reduced to low potential and high potential is emitted from the delay circuit and the telephone line between subscriber B and C will thereby be broken. 8. System according to claims 1 and 5, characterized in that the two storage devices are combined into one for storing telephone numbers under monitoring, and are thus used for temporary storage for automatic number selection. 9- System according to claim 1, characterized in that when subscriber B is monitored by subscriber A and subscriber A's telephone number is stored with B and a person visits subscriber B and operates the bell at the front door which is equipped with a door phone, this will cause the door phone to be connected to the telephone line and telephone number data for subscriber A that is stored in the storage device of group I at B will be decoded quickly so that numbers are automatically dialed and calls are made at A and the visitor is connected directly to subscriber A. 10. System according to claim 1, characterized in that when a thief commits a burglary at subscriber B who is monitored by subscriber A, whose telephone number data is stored at B, a control switch will be operated to energize a circuit, and the telephone number data stored in the storage device by group I is quickly decoded and calls subscriber A automatically, and if A's telephone is busy another circuit is energized by a certain short signal from the telephone exchange which will cause calls to be repeated until connection is made, and a probe signal is sent from subscriber A so that B transmits a number of pulses indicating that B has been broken into. 11. System according to claim 3> characterized in that when a pulse signal with a different or equal number is sent from subscriber A to subscriber B in the order in which they are stored in the sequence circuits of subscriber B, remote control units are selected which are operated by signals which are sent to B later and output signal is emitted from the selected device for remote control. 12. System according to claim 10, characterized in that when number selection is made automatically from subscriber B to A in the event of a break-in and surveillance from A, and an investigation signal is sent from A which causes B to send a pulse signal with a number of pulses in numerical order which are counted by A for identification of the place where the break-in has taken place, so that several places can be monitored at the same time. 13. System according to claim 9, characterized in that after a visitor has operated the doorbell at subscriber B, the doorphone is connected to the telephone line by setting a flip-flop circuit and the clamp with low potential is given a high potential which energizes a relay that makes the connection. 14. System according to claim 10, characterized in that when a break-in occurs at B, a circuit is energized • so that number selection occurs automatically to the monitoring subscriber A for sending an alarm signal.