SE434784B - SOUND TRANSMITTING DEVICE WHICH IS CONNECTED TO THE PUBLIC TELEPHONE - Google Patents

Description

Of the application-dependent information, that its microprocessor-based equipment is built in a single-card solution where the card is arranged to connect to the telephone line and the telephone network when detected and initiate conditions corresponding to an open hand-held microphone, to determine whether the normal dial tone is obtained within a predetermined first time period, eg 9-20 seconds, to accept the dial tone only if it persists for a predetermined second time period, eg 2 seconds, to initiate conventional dialing within the telephone system to an arm center, to wait for a B-answer and decide whether this should be approved or rejected and in the case of an approved B-answer cause transmission of the established arm.

In a further development of the inventive idea, the microprocessor is arranged in a special way in the arm transmitter device so that power supply of the microprocessor will only be possible at predetermined times.

What can essentially be considered to be characteristic of a device according to the invention appears from the characterizing part of the following patent claim 1.

Currently presented embodiments of a device having the characteristic feature significant to the invention are described in the following with simultaneous reference to the accompanying drawings in which, Fig. 1 shows in principle diagram form the new device, Fig. 2 shows a flow chart, Fig. 3 shows in principle diagram a more detailed embodiment. Fig. 4 shows in diagrammatic form a tee fund included in the device, Fig. 5 in principle diagram form shows a control circuit included in the teephone, in Fig. 6 shows the principle of a decoder, Fig. 7 shows a principle diagram of a utilized clock circuit, Fig. 8 in diagram form shows in the circuits input impu1s.

In Figure 1, a telephone line (subscriber line) included in a telephone system, for example in the public telephone network, is shown with T. The arm transmitting device comprises a central unit in the form of a microprocessor 2 and an adaptation part connectable between the microprocessor and the telephone processor. The adapter part 3 receives signals from the telephone line and adapts these to the microprocessor 2 suitable signals. Similarly, the microprocessor signals are converted to signals suitable for the telephone line in the other transmission direction.

The adapter part 3 comprises, in a manner known per se, a tilting step on its output towards the microprocessor. Figure 1 also shows, with dashed lines, previously used conventional tone transmitters and tone receivers, which are now thus replaced with signal processing circuits in the microprocessor.

The microprocessor is connected to or belongs to a structure register in the form of an (S) -PROM memory 4. In said structure register the intelligent information is stored which allocates the application-dependent information in question. The structure register is arranged in an easily interchangeable manner, and by allocating different structural memories to different algorithms, one can in a simple manner determine, change, complete, etc. both at new installation and afterwards, the characteristics which are to be significant for the arm position.

The microprocessor is also connected to one or more arm sensors 5. The power supply circuits, not shown, are furthermore arranged such that power supply of the microprocessor takes place only at predetermined times 11.

The present device uses a microprocessor-based single-card solution, which in accordance with the above is intended to replace previous technology based on so-called four-card systems. The basic model for the function of the new system is shown in the flow chart according to Figure 2. The invention relates to a certain part of the program which realizes the flow. More specifically, the new device is realized in the embodiment shown in Figure 3.

Testing of the desired program flow and development of a multi-card solution has been carried out in practice. In connection with the development of the invention, connections have been made to the programming language for Motorola's microprocessor 6800, assembly language for editing, assembling and linking various program parts. Also connections have been made to certain physical components such as type 6810 programmable logic PIA 6820, and more.

In the practical embodiment, the invention has been linked to systems based on Motorola's 6800 and Intel 8080 which are hereby judged to be substantially equivalent. Other parts of the current alarm system have largely been based on 6800, which is why this has been especially preferred. CMOS solutions (COSMAC) are also possible in the context.

In the following, an analysis of existing signals shall be made.

The definition of alarm is that at least one logic signal, one or zero, has 128 lasting, for at least a few seconds, change value. Each state change must be able to be made with a unique alarm message, which also distinguishes the type of change: 0 - 1, alarm, or 1 - 0, reorder message. When an alarm is detected, the card, hereinafter referred to as LSS 11, must be connected to the telephone network in such a way that it corresponds to a raised telephone handset. In this state, the LSS 11 card must be able to determine a normal switching tone, 420 Hz, obtained within 10 - 20 seconds. Approval of the tone takes place only if the tone remains permanently for at least a period of 2 seconds. After approval of the dial tone, dialing takes place in the usual way by pulse transmission with a 40/60 ratio and a 500 ms pause between numbers. During at least 3 ring signals, RG (1 RG-10 s), a response from the control panel in the form of a 1 kHz tone, B response, is expected. This tone must be approved or rejected according to the same rules as the 420 Hz tone. If the B-response is also approved, the alarm transmission of a frequency-modulated signal takes place at 10 pps. The alarm must end with a check digit. The acknowledgment starts from the station with the number 1 kHz tone renewed. This is requested for about 4 s and is approved after 400 ms. When the receipt has been received, it is examined whether several alarms can be transmitted, in which case these are transmitted in turn in the same way as above until all alarm messages have been transmitted. The connection is then disconnected. Should no response be received at any time 7801782-9, the system shall disconnect and start again from "alarm detected".

After eight attempts at the originally given telephone number, it is switched to a backup number and even fails, the system tries to initiate itself.

The above suggests a natural division of the program into three parts: i 1 start-up (restart) of the system 2 monitoring 3 transmission The initialization when the system is started must contain the correct control line for the programmable logic and control of the relays in the telephone unit to the correct starting position. In addition, fields, counters and flagpoles must be prepared for the monitoring part of the program. In the next step, the monitoring, the information is processed: collect, tabulate and make decisions. Upon transmission, a tone message must be sent and received, which also means information processing.

In particular, connection of connection is included. For time monitoring and measurement, an interrupt routine at certain intervals must provide real-time adjustment.

When the system is started or restarted, a well-defined sanctioning operation must be performed in sequential order: the programmable raw material must be given the correct control word and starting position, tables and specific memory positions must be screened, stacks initiated and the interrupt mask removed. At this stage, there is no need for subroutines. when processing information under supervision, task 3 is divided into subroutines as follows: 1 retrieval of information- 132 2 tabulation of information- LPK 3 decision-making and coding of critical information for alarm messages - CNV, KSIF. 7801782-9 The fourth subroutine, KSIF, could be housed within the third, CNV, but has been rendered independent due to its distinctive character. 132 is described in more detail below.

For the transmission of messages, there is a similar division of the functions into 3 subroutines. The three functions that must be solved are, 1 connection ice is copied up 2 tone messages are received 3 tone impulses 1400/1900 Hz for sending tone messages.

Functions 1 and 3 can be passed through appropriate programs in the program without the need for the specific jump of the subroutine, with their fundamental importance in other systems making separate development convenient. Function 2 is needed in several ways and is called in different ways, so a straight code in the main program requires a subroutine.

The three subroutines for transmission corresponding to the above functions will now be: 1 number typing by puisation of the line - CP. 2 tests of ton 3 ton imprinting The subroutine CP is included and described in the following.

The hardware construction is shown in Figures 4, 5, 6, 7 and 8.

In the case of teifonidei, this does not differ in this context from previously known teifefonideïar. Three different rows A, B and C must be operated in the following manner. Figure 4 shows the standard situation. The first step when connecting arm transfer is to connect the LSS 11 card by pulling the A-line.

When the coupling tone is now obtained (420 Hz), the B-line shall be short-circuited towards the station and the dialing of the C-line shall correspond to the numerical display on the 7801782-9 dial.

In accordance with Figure 5, the relays are controlled by the I / O unit.

In the case of the memory organization ("chip select"), a microprocessor type 6865 has so-called memory addressing. The standard solution for the memory organization is then to load the program at the highest addresses, especially the reset and interrupt vectors, write / 'read the memory at the highest to Designation, activation, then takes place with a decoder (74138) in accordance with Figure 6 which is synchronized with the clock and gated with the VMA signal (Vaiid Memory Address), deis for three address bits for designation 1 - off - 8. With lk PRDM at address S / C 400 and 128 byte RAM at address 00, the solution is according to figure 6. In the smaller PRDM, card-specific information, card identity, number ti11 iarmcentrai, etc. are stored.

As for real time clock and interruptions, the system clock operates at 1000 MHz. It is difficult, however, to programmatically adapt the system to real-time only due to pairs, different paths in different situations, etc. Therefore, a calculator is used to communicate the frequency at 11 a period of 8, 13 ms. Did this happen? by connecting the clock to the trigger input of the counter and connecting the appropriate output via inverter to the IRQ input of the 1 ßPUzn. The interruption routine affects flip-flops that are announced in the main program.

To enable the program to set the real time clock, RTC, the reset function is gated. This results in synchronization with the program and RTC, but the interrupt routine is not triggered, see Fig. 7.

Then an address with A15 = A14 = A10 = 0 is issued no '| 1stä' | '| es RTC.

In terms of tone transmission and reception, a square wave on the I / O unit's B-port, bit 0, is generated in a similar way as when pulsing with the C-line. The signal is then passed through a square-pass filter with a square cut at the cut-off frequency of 2 kHz to the output. "Sign out" in Figure 4. Compare also Figure 8. When receiving tone, there are two philosophies: hardware defrosting in two logic signals via bandpass filters or a software processing of the signal as the circuit is converted from sine to edge wave. In both cases, the reshaped insignia is inserted into the most significant bit of the data bus via a data signal unit (74151).

A comparison between the two methods shows that the software solution is completely superior in that the fewer number of components that are returned is not offset by the differences in program memory space. In both cases, the stability of the signal must be determined programmatically.

The following basic functions precede dialing to one or more remote control panels (ïarm receiver) scanning of input devices and detecting changes determine if change is critical, permanently signal if 10 pps on connected line receive tone message SS-ABL is a circuit board intended to transmit via teïefonnätet. The circuit board is built on a K2 card in the BYB 101 kit. It is placed in a flat box (wall mounting) with dimensions of about 80 x 300 x 260 mm. Adjustment circuits such as SV stabilization, level adjustment, drive circuit, screw pins, etc. are mounted on a board in the box so that external connection via screw terminal.

Power consumption is less than e11er Tika with 3 N.

The SS-ABL circuit board can be used for a single-digit number transmitter which, at an arm of a maximum of 128 inputs, dials a programmed telephone number and transmits a message about the arm to an arm receiver, after which a message is awaited.

The alarm transmission takes place at 1900/1400 Hz in 50/50 conditions.

The main program should11, with the subroutines used implement the feed in figure 2. It breaks down into 3 parts: 7801782-9 IEQ equipment, RN routine monitoring and alarm start, LPG alarm program.

Fw fl bmmüæim fi wmgVNuwmuLåænmM, ms fi mt control word to the programmable I / O device. Then some of these outputs are presented. The write / read area used, S 00 - 7 F is reset by using indexed addressing in a loop. A semaphor for disabling parts of the interrupt routine is set. The instruction TST distance RTC ensures that the address decoder gives a reset pulse to the real-time clock. The start is initialized to S 7F (at the top of RAM) and the interrupt mask is removed.

Regarding monitoring and alarm start, the following takes place. After each acknowledged alarm transmission, the counter TRY must be set 8. This is the only reset the main program makes after a completed alarm transmission. The monitoring routine calls for three subroutines with well-defined tasks: I32 reads the inputs, LPK compares with previous readings and CNV decides if any change is critical. If so, the alarm code is calculated and placed in LRMNR, + 1, + 2 (the spelling denotes three consecutive bytes, basic address LRMNR, the following byte LRMNR + 1, etc.). The LRMVX cell is set to indicate an alarm. In the main program, LRMVX is tested. As long as LRMVX = 0, the monitoring continues.

When LRMVX not = 0, the correct telephone number - address must be placed in NYSIF, + 1 according to: LRMVX = 1 NYSIF, + 1: = S 8000.

= - NYSIF, + 1: = S 8010.

The card's identity is stored on SPROM and masked to the alarm code, after which the check digit is calculated. The program pauses by setting cell I = -1. The interrupt routine reduces this cell once every eight ms and thus counts around to 0.

Meanwhile, the scanning of the entrances continues.

During the alarm transmission, the following takes place. By placing the B-port on the I / O unit 2, its second bit and thereby the A-relay are set. '7801782-9 10 Address to telephone numbers is transferred to XL + 2, +3. In this way, the program can communicate with the CP routine without changing the address in NYSIF.

Inputs are given to the TTX subroutine to request whether there is a dial tone. At the address AMIN there is a vector describing 420 Hz.

If TTX approves the switching tone, recurrence occurs with ACCA positive, ie the 7th bit is reset. This is being tested. If the ACCA is negative, it is assumed that the dial tone did not exist. The subroutine CP is called for number transmission. CP responds with ACCA = SC as the number series ends and with SD if it is an area code with several tone messages to wait for. X points to the last digit read. The main program increases X, compares with SD and continues if ACCA does not = SD. Otherwise, return to position L.

After the number series ends, 1 kHz response tone is expected through a loop that makes 4 calls by TTX. At the address BMIN there is a description of 1 kHz. If no tone response is received when asking for a dial tone or when asking for 1 kHz from the alarm center, the A-relay must be released (hand-held microphone switched on) and the counter TRY reduced. As long as TRY is greater than 0, the program continues with the same value in NYSIF, + 1, ie without changing telephone numbers. If TRY = 0 is switched to the backup number at the address S 8020. If TRY becomes negative, the system tries to initiate itself.

Pause long enough to ensure disconnection.

If a response, in kHz, has been received from the alarm center, quick scans are made with TTX until it responds negatively, ie ACCA less than 0, which means that the kHz tone has ceased and the receiver is ready to receive a message.

The main program now calls the subroutine TI after giving the address of the first digit via X and setting the stop sign, SC.

After the tone pulse, 1 kHz is requested again. If a negative message is received, the program returns to NTON mode, hangs up and tries again. '7801782-9 11 If a positive message is received, scan with CNV if more alarms are relevant.

In this case, these are calculated to LRMNR, +1, +2 and LRMNR remains = 0. If no more alarm is current, LRMVX is reset. Test on LRMVX then gives the main program information if all alarms have been sent or more are present.

If there are more, the alarm code is calculated as if on the control figure. Via a call from KSIF on line 125, the main program waits for the 1 kHz tone to run out and then transmits the next alarm.

After the alarm transmission has been completed, possibly with some missing voice response, the program disconnects the connection and returns to monitoring.

Failure to send a message may occur if a maximum queue (eight alarms) is waiting for transmission. The alarm center's receiver has a time monitor that allows a maximum of six alarms on the same call. There is also a program list for relocable programs.

In the following, existing subroutines will be described. a) 132 - Reading from card 132 (116) The subroutine is described in detail below. Its function is to retrieve information from a maximum of four cards 132 (116). If the card is connected, a response signal is received at designation. The information is transferred to an area in the write / read memory as a direct copy of the state of the inputs. b) LPK - processing of information The subroutine compares two areas of 16 x 8 bits, LAREA and KAREA. In the initial position, both are reset. During the monitoring, the condition of the entrances is copied via 132 into LAREA, after which LPK compares with KAREA. When a difference occurs, the cutter identifies which input the difference occurred on.

The identification involves the construction of an internal code comprising a byte, an IK byte: 7801782-9 12 O Alarm Bit 7: Alarm type 1 reset Bit 5-6: Card number, 0-3 Bit 3-4: Eight group, moduï, on the card, 0 -3 Bit 0-2: Input in the eighth group, 0-7 IK changes must11 correspond to a counter that is counted up each time an IK change is identified.

Fiöde: (LPK sTART) _____ <AREA / KAREA> Yes Calculate IK change <<Calculator started? > Yes ----- 'No ¿- <Free counter (8 pcs)? > Yes B ida Count up (start counter ¥ -------- - ä F1era ski11nader> lm ---> (Rice) The counting is synchronized with the interrupt routine and therefore takes place every eighth ms. G? So17a2-9 13 c ) CNV - Besiut on underiag of processed information.

In this program, the counters that LPK started and counted are announced. If someone has reached a critical value, the corresponding IK byte is converted to an ïarm in a field of 5 bytes with a symbolic start address LRMNR: In LRMNR, +1, a code for LSS 11 is specified. Otherwise, the pieces in IK exchanges are separated as above. At the same time these are increased by 1, ie 0-3 b1ir 1-4, 0-7 b1ir 1-8.

To ski on arm and reset, LRMNR + 4 is increased by four on reset, ie 1 arm 30318 corresponds to reset 30358.

After conversion, the change in KAREA is acknowledged (cf. above). The alarm will now be sent regardless of whether a return to the previous state occurs. In addition, a cell is set up to tell the main program that the arm exists. d) KSIF - Calculation of counter figures.

Input ti11 KSIF are the five digits in the ïarmnumer, ie five bytes in a fäit that starts at the symbolic address LRMNR. KISF is tailor-made for decimal numbers and does not work for hexadecimal numbers. f As an output, KSIM in LRMNR + 5, a11th as a sixth byte in the field, gives a decimal counter digit such that the number of the six digits is set to 5. e) TTX - Test if the received tone is correct.

Subroutine to determine if an insignia is within an approved frequency range (center frequency + -5%). The input time is the time that the tone test is to be performed (maximait 105) on how long the correct tone must be obtained to be approved. In addition, the index register points out two bytes where the lower and upper frequency 7801782-9 the received tone should be within.

The received tone is obtained as an edge wave applied to D7 at address TM.

As output, ACCA is obtained positive if the tone is approved, otherwise negative. i (TTX START) '___-_- a No11stä11 fïankräknare _-- <Flank? > Yes No No Count fïank --- <Nätinterva11 slut? > Yes <Approved tone? > lga No ACCA: = 0 (RTS) -No-- <Totaïa time sïut? > lya ACCA: = 0 (RTS) f) CP - C-relay Pulsation.

The subroutine is described in detail 1 below. It should solve the task of drawing the B-line (cf. 4a) and imposing the C-line with a 40/60 ratio and a 500 ms numerical space. The input to the subroutine is two bytes at the symbolic address XL + 2, +3 which stores the address to the first digit. Output data is given deïs in ACCA and deïs in å X: N ACCA = 0 The number transmission was interrupted after sixteen digits including ski signs for area code 7801782-9 15 ACCA SS The number transmission was interrupted due to stop signs ACCA SD The number transmission was interrupted for renewed tone reception.

The index register points to the most recently entered figure if ACCA has assumed the value C eiier D, otherwise change after the most recently entered figure.

Example of a series of numbers: 0 5 4 D 1 6 2 0 3 0 C. 9) TI tone tone The subroutine should generate a square wave by alternately positioning one and no11 in the I / O unit. In this way, a frequency-modified numerical message must be transmitted. Number of numbers is 400 ms with 1900 Hz and each digit is transmitted with 50 ms 1400 Hz puis me1-¶ ian so ms 1900 Hz. in Indata is that the index register points to bytes for the first digit to be sent11. When a C is found, the series is terminated.

Fiöde: (TI) X points to new number <400 ms 1900 Hz i (Ris> <_- aa- <c?> Luej __; so ms 1400 Hz The number sent?> -J lyej 50 ms 1900 Hz 7801782-9 16 In the following, the input subroutine I32 will be described in more detail: a) Function A maximum of four cards, each with four modules with eight inputs, will be activated for reading. For pointing out cards, there are two address bits called CAO and CAI. For designating modu1, there are two more address bits. To activate a designated card, a Read / Writesignaï must be held high and a strobe sign1 must go by Train.

If there is a card attached to the designated address, it responds with a 'readysignaï. The module can then be loaded. b) Input and output data The card address bits CAO and CAI are attached to the symbolic address WPIAN + 1, bits 4 and 5 respectively. Bits 0-3 may not be changed, bits 6-7 are reserved for extension to 11 32 cards. The contents of PIAH + 1 can be read on PIAR + 1.

The module selection takes place via PC1 and PC2; These are controlled individually via PIAW + 3 one code below: 0 XXX 0 - 7 S / R 7 6 5 4 3 2 1 0 Bit O: 1 Set 'O Reset Bit 1-3: Vai of PCO-PC7 Bit 4-6: Equivalent, set 0 Bit 7: 0 means S / R only bit 0-3 The R / W signal is given via PC7 which is set high at program initialization and strobe takes place via PC6, also high at initialization¿ The RDY signal is attenuated at bit 7 on symbolic address TM + 3. (Etta means no RDY). 7801782-9 17 Me11an1 storage of PIAH + 1 takes place at a direct address (one of the first 256) with a symbolic designation CT50.

As output, the eight groups are copied into 16 consecutive bytes with base address LAREA. c) Use of registers and memory sequences The index register points out the current byte for eight group entry, initialized to LAREA.

ACCB is set 1ika with SC as the code means PC6: = 0 when ACCB is stored in PIAH + 3. ñkas ACCB with an ïagras in PIAH + 3 sets PC6 high.

ACCA is used for meïïaniagringar, specie11t when loading from PIAR. The appearance of PRAN + 1 1 is entered. Bits 4 and 5 are assumed to be 1.

As a result, the first card address is k1ar. Then inc with S10 ti11s ms: mr 1: '7 6 5 4 3 2 1 0 0 0 0 0 XXXX 0 0 0 1 XXXX 0 0 1 0 XXXX 0 0 1 1 XXXX 0 1 0 0 XXXX Cancel, bit 6 = 1 The card addressing is now well suited for a loop with interrupt conditions in bit 6.

If the modules were called in the order 00, 01, 10, 11, 00 sku11e for controlling the following PC2 PCI series, PIAH + 3 is given: (2,4), 3, 2, 5, 3, 2, 4. By substituting give the order 00, 01, 11, 10 the series 4, 3, 5, 2 is available.

The strobe entry takes place in a 1oka1 subroutine TEADS that updates the index register, issues a strobe, asks for RDY and decides whether entry should take place. If RDY is missing, no loading takes place. 7801782-9 d) Fïödesschemaz (132) Load storage address -----> Stä11 out card address Module 00 READ Eight group 01 READ Eight group 11 READ Calculate new card address -No- <Kïar> J9a (RTS) READ takes place with and 1oka1 subrutin. When I32 is called by the main program and the 1st subroutine has a relapse within I32, the maximum stack height is II (2 for each subroutine pile 7 at any IRQ) and the time is 16. If NMI is entered, the maximum stack height must be increased. 7801782-9 19 Fiöde for 1oka1 subroutine: (READS) _, L_ Strobe 4- -14 RDY? > jga No Load and iagra indexed -___-> Aviägsna strobe Increase index register (RTS) e) Programïista for reiokeable subroutine The impulsion routine CP is performed as follows. a) Function With the A-rail pulled, the B-rail must be pulled. After a couple of seconds pause, the C-range should impulse dialing with a 40/60 dial-up ratio and at 500 ms digits. Numbers me11an 0 and 9 occur only 0-One pu1s, l-Two puïs, ..., 9-Tio- puïs.

A maximum of sixteen digits in a feed is sent. Area numbers may occur, ie that interruptions must be made for a new dial tone. b) Input and output The numbers are burned into a 256 x 4 bit PROM on the symbolic address SPROM. This PROM is connected to the least significant bits of the data bus. Three different series of digits (teï-nr) can occur at the respective address SPROM, SPROM + S10, SPROM + S20 (S indicates -hexadecimaï digit). The current number is specified in the two bytes located at the symbolic address XL + 2, + 3. When the current number is also designated in NYSIF, +1, the content in XL + 2, + 3 may be affected. 7801782-9 The A, B and C relays are operated with bits 2, 3 and 4, respectively, at the symbolic address PIAN + 1, the B-port of the I / O unit. One means drawn relay, zero released. Other bits must be reset during the impulse.

As output, different values are obtained in ACCA: ACCA = 0: The number series interrupted after 16 digits.

ACCA = SC: The series of numbers interrupted after complete transmission.

ACCA = SD: Pause, the series of numbers interrupted for a new dial tone, cf. the description of the main program. ~ If ACCA = SC or SD, the index register points to the last digit entered (SC or SD). If X is increased by 1 and stored in XL + 2, +3, after tone reception CP can be called again to dial the next part of the number.

Note that XL + 2, +3 must not be changed in between.

Read-in numbers are masked into the ACCA and approved if they are decimal.

Then storage in SFPOS. For each pulse sent, SFPOS counts down one step. When SFPOS is less than 0, the digit has been sent.

SFPOS is also used for pause counting. The principle for pause S00 ms is seen in the following program sections.

LDAA L DEC SFPOS 6 cycles 10 cycles x 256 times BNE L 4 cycles DECA e 2 cycles BNE L 4 cycles Time: 10 cycles x 256 x K + 6 cycles x K _ Each clock cycle is taken 2 us ie total (256 x 10 + r6 ) x K x 2us Neglect the six and calculate K so that the expression becomes 500 ms. K is then selected 98 at numeric spacing; 21 a) Fi ödesschema: (CP i Paus --_> Pegg / a ut next digit 500 ms Read in designated digit tiii ACCA <Digit decimai, 0-9?> _- No ya Send the digit -No- <16 digits send ?> ya ACCA i (RTS) <e) Programii sta for reukerable subroutine The times checked with the analyzer HP 1611A Memory position are performed in accordance with the following. a) Basic physical addresses according to address decoding 7801782 ~ 9 Address decoding is performed in terms of hardware with IC circuit 74LS138 which is connected to activation inputs type CS (Chip Seiect) on RAM and PROM and type Strobe on 74LS251. In addition, an address bit is gated during decoding. In Table A6: 1, various address bits are indicated which are locked in terms of hardware with one or more so that the correct unit is to be pointed out. The dashed line indicates the undefined address bit and the X indicates that the address bit means for designation within the selected physical unit.

An unconnected address bit can be given any value. When writing the program, the regein has been to put these pieces noii, cf. the address areas specified. 7ao1? S2-9 1s 14 13 Rwil 0 o ø Rïct ¶ oo - TM o 1 - PIAR uo _ Prnw 1 o} _ spann '1 o - Ledig 1 1 Paon 1 1 - 12 0 1 - - - - - - - - - - 0 1 - - - - - - - xxx 1 0 - - - - - - - - xx 1 1 - - - - - - - - xx 0 O - - xxxxxxxx 0 RHM: ß means that the address bit should be- 0 for direct address PIAR: A1 A0 must not be present, ie not S4803 RWM 800-7F RTC SHOO TM 84400-4407 PIAR 84800-4802 PIAH $ 8C00-8C03 SPROM 88000-80FF PROM 8C400-C7FF Abbreviations No Address address1111 also of SFFF8-FFFF, interrupt and reset vectors Run-write / 1äsm1nne, type RAM RTC-Reaïtidskïocka cf. 4c TM-Tonmottagare, only ansïuten ti11 07 svnon-structure Pnon, only no-ua PIAR-1n1ä§n1ng from r / o- unit PIAH Writing in I / O unit PROM Program 7801782-9 23 No. Name PG TTX CP TI 132 LPK CNV KSIF IRQ 00 I xxx +1 +2 x +3 x 09 +4 +5 SMF 1 2 3 4 XL 5 6 7> <> <> <> <> <> <> <> <CRUNT CVARV CT50 xx 10 LRMVX 1 TRY 2 NYSIF 3 +1 4 LRMNR 5 6 7> <> <> +1 +2 +3 18 + 4 19 +5 Stoppkn FLAG OK FLANK TCELL TIMAR 20 SFPOS xxx fl1 rn :: - ra av: - xxxx: § xx b. X C: cs es E: ca Fig A6 = 2 Fäïtt LAREA 30-3F 132, LPK, CNV KAREA 40-4F I LPK, CNV CAREA 50-67 LPK; CNV, IRQ Stack 70-7F 7801782-9 As far as the above-mentioned structural register - SPROM - is concerned, this can be used to store, for example, the teief number ti11 1arm- centrai and viiket cards that send iarm. Without extending the size of the program memory, a program can be produced according to which the delay is variable moduivis referring to the structural register according to the following code: F - 0.65 7 - 1.3s 6 - 2.0s 5'- 2.6s en 4 - 3.25 p3 - 4.05 2 - 4.55 1 - 5.2s 0 - 10s Resistance is delayed aïïtid 10s Furthermore, the program with reference to the structural register can determine whether the break or 11 siut is "norma1t" tiiistånd resp inversion aiïså 1armti11stand: 1 - For the moduien, the break is 1armti11stand moduien gäiier att siutting är 1armti11stand Since one is not always interested in restitution notice, this can also be stated moduivís in the structural register; 1 - Re-determination notice must be given 0 - Re-determination notice must not be given With the expansion of the program memory that exists when Zk EPROM is available, a transition can take place so that the program structure is also referred to SPROM. In the program memory, a main program is set to have fixed subroutines and also variable subroutines. The transmission routines CP, TTX and TI for digit impulse, tone reception and tone transmission, respectively, are well suited as fixed subroutines.

The information processing, on the other hand, may vary depending on the user's system. The basic structure is acquisition, processing and processing. 16 selectable subroutines can be loaded into the program memory. The structure can then follow the subroutine frequency in 32, LPK, CNV in code 0, 4, 8 or TM8, LPK, CNV in 1, 4, 8 where I32 is numbered 0, TM8 is numbered 1 and so on.

S1 u fl again, of course, there is the possibility of going through bit tests in the main program to go different ways, modifying algorithms or via reference to the structure register to give counters different initial values. The structure register is arranged easily interchangeably in, for example, insertable and retractable in actuate card, in respective arm position.

The invention is not limited to the above as an exemplary embodiment but may be subject to modifications within the scope of the appended claims.

Claims (2)

a 7801782-9 26 PATENTKRAV 1.) An alarm transmitting device intended to be connected in an arm system, at an arm position therein, to a telephone line (T) in the public telephone network, and to be accessible to or include one or more arm members, for example the arm transmitter (Si, where the transmitter). The arm transmitting device comprises a signal processing unit (2) designed as a microprocessor with signal receiving and signal transmitting circuits and an adaptation part arranged between the transmission and said unit, characterized in that the microprocessor detects from the adaptation part of the adaptation part (s). signals and works directly on them, that a structure register (memory) is arranged to include application-dependent information which is assigned to an affected device, that the structure register is indicated or is included in the microprocessor, that the structure register is arranged interchangeably to enable simple completion, modification, etc, of the application-dependent information, that its microprocessor -based equipment is built in a single card solution where the card is arranged to connect to the telephone line and the telephone network when the arm is detected and to initiate a state corresponding to an open hand microphone, to determine whether a normal dial tone is obtained within a predetermined first time period. seconds, to approve the dial tone only if it persists for a predetermined second period of time, eg 2 seconds, to initiate a conventional call within the telephone system to a call center, to wait for a B-answer and decide whether this should be approved or rejected if approved B- response cause transmission of the detected arm. 2. A device according to claim 1, characterized in that the microprocessor is arranged for current supply circuits in such a way that power supply of the microprocessor is possible only at predetermined times. a '