DE69734112T2 - METHOD AND DEVICE FOR CALLING SWITCHING DETECTION - Google Patents

Description

AREA OF INVENTION

The The present invention relates to a method for detecting a Rufabschaltung in a line circuit and a device for detecting a call disconnection in a line circuit. With Call-disconnect detection is the detection of the change from that applied state to the off state when calling signals carried out become. The line circuit controls and drives the ringing signals in the telephone lines. The line circuit also provides the DC line characteristics such as the apparent battery voltage, the line feed impedance and the current limit. One of the main functions the line circuits is a ringing signal to the connected Phone. There may be a loop that this Function supported and controls the DC voltage between two subscriber line wires.

BACKGROUND THE INVENTION

The said DC loop can also include the phone and can, as previously mentioned, also control the DC voltage between the two subscriber line wires.

• – Sie stellt die Teilnehmerleitungsstromzufuhreigenschaften ein
• – Sie erzeugt das Rufsignal
• – Sie nimmt das Rufsignal wahr
• – Sie detektiert die Rufabschaltung
• – Sie detektiert die Schleife

The DC loop can therefore often provide the following functions:

• - It sets the subscriber line power supply characteristics
• - It generates the call signal
• - It takes the call signal true
• - It detects the call cancellation
• - She detects the loop

The DC loop also determines the internal battery and the DC supply resistance to the line.

The DC supply characteristic is determined by detecting the line voltage, and then the DC loop controls the line current through the loop. In 1 Figure 5 is a simplified diagram of the DC loop during a ringing mode of operation mode.

The line current I _L follows the equation:

wobei

I_L

= Leitungsstrom

U_L

= Leitungsspannung (Spannungsunterschied zwischen A- und B-Draht)

Z_F

= Leitungszufuhrimpedanz,

ω₁

= Poleckfrequenz, 1,5 Hz Gleichstromschleifenfilter, alternativ 170 Hz in der Rufsignalfolgenbetriebsart,

GR

= Leitungsstrom ist GR-mal dem Strom durch RDC,

RDC

= externer Widerstand,

R₁

= interner Widerstand stellt die Leitungszufuhrimpedanz ein,

I_bat

= Stromgenerator und

gm

= Transkonduktanzfaktor

From the above expression, the output impedance of the circuit to the line becomes:

in which

I _L

= Line current

U _L

= Line voltage (voltage difference between A- and B-wire)

Z _F

= Line feed impedance,

ω ₁

= Poleck frequency, 1.5 Hz DC loop filter, alternatively 170 Hz in the Rufsignalfolgenbetriebsart,

GR

= Line current is GR times the current through RDC,

RDC

= external resistance,

R ₁

= internal resistance adjusts the line supply impedance,

I _asked

= Power generator and

gm

= Transconductance factor

The Internal battery voltage is provided by the current generator Ibat and determines the transconductance factor gm.

Of the Power generator Ibat is in all modes except the Call signal mode constant.

During the ringing mode, when the ringing signal is on, the ringing signal is superimposed on the internal battery voltage. This voltage is generated by a constant current. The ringing signal is achieved by superimposing an alternating current on the constant current. The power generator Ibat thus forms the ringing signal, and the battery voltage can be a rectangular ringing signal as in 2 to shape.

The US 4,731,828 A discloses a circuit for detecting call disconnection. This circuit comprises a limiter to give a ringing signal a rectangular shape, the rectangular form here losing 50% duty cycle when a subscriber's telephone is picked up. Two counters count the samples taken by the signal, one the positive values and the other the negative values. Therefore, a call disconnection is detected when the difference between both counters exceeds a call-disconnection threshold.

The document EP 0 116 291 A2 discloses another system for detecting call cancellation. The system of this document uses a comparator which compares the calling signal to a fixed reference voltage near ground at a rate much higher than the frequency of the calling signal. The resulting comparison signal, which is a square wave signal, is supplied to an up / down counter whose output is evaluated by a logic circuit for detecting call interruption.

Other devices for detecting Rufabschaltungen are from the US 5,402,482 A and the US 4,540,853 A known.

SUMMARY THE INVENTION

The The present invention provides a method for detecting a Rufabschaltung according to claim 1 and an apparatus for detecting a call shutdown according to claim 2 ready. Define the dependent claims preferred embodiments the device.

To the Detecting a call disconnection detects a call disconnect detector first the applied state of the load of a telephone circuit Compare the value of the zero crossings and detect the change the load during losing weight. While the on-hook state, the call signal has no DC component on, but while the off-hook status even includes the call-disconnect detector measuring the DC component.

One High frequency master clock oscillator of a much higher frequency than that the call signal is used. The main clock is divided by a counter, so the counter cycle corresponds to the call signal. The counter controls an SC filter which forms the ringing waveform and the battery current generator controls. The counter is used as reference.

The Detection of hang-up and take-off is accomplished by detecting a Voltage at a node in the DC loop, which is proportional the DC line current is reached. The zero crossings of this Voltage creates a pulse in both the positive and the negative negative zero crossing of the zero crossing detector. The counter is switched into a memory when this pulse occurs. Of the Zero crossing of the previous and the current call cycle is stored in the memory. A counter decides the difference between the zero crossings the previous and current call cycles. The call-disconnect detector is also with another counter provided by a number of consecutive Call cycles with "no Phase difference "established Zero crossings certainly.

The call-disconnect detector comprises a reference counter which controls the battery current generator, a zero-crossing detector and two other counters. The first counter decides the difference between the zero crossings of the previous and the current call cycle. The second counter counts the number of consecutive paging cycles with "no phase difference" or "phase difference" depending on which mode the paging detector is operating. After the zero crossings of the call signal have been established, the counter changes operating mode and counts "phase difference" If the number of ringing cycles is "phase difference", the ringing detector detects ringing off.

This is a digital measurement of the phase, being both the positive as well as the negative zero crossings are detected. The Detection of call cancellation must be made quickly, the Decision must be made after the first changed call cycle.

SHORT DESCRIPTION THE DRAWING

1 Figure 5 is a simplified diagram of the DC loop in the paging mode.

2 is a simplified call signal graph.

3 Fig. 10 is a diagram showing the function blocks of call-disconnection detection according to the invention.

4 Figure 11 is a graph showing the relationship of the phase between the Ibat generator and the current in the line.

5 Fig. 10 is a diagram showing the cells of the call-disconnection detector according to the invention.

DESCRIPTIONS A PREFERRED EMBODIMENT

1 shows a line load ZL connected by A and B wires 1 , The line voltage U _L on the two wires is passed through a transconductance amplifier 3 which converts them into a stream derived from a UDCO node. The battery _{current generator} I _BAT 4 conducts electricity to the UDCO. The internal resistance R ₁ 5 sets the line feed impedance. A low pass filter 6 between the node UDCO and a buffer 7 Pre-UDC output prevents the voice signal from affecting the DC supply characteristics. The filtered UDCO is controlled by a comparator 10 compared with an analog mass. The zero crossings are done by a call-off detector 11 detected. The filtered UDCO is also controlled by a comparator 12 compared with a threshold, and a Rufstromdetektor 13 detects whether the line current exceeds a certain XLD value. The UDC is with a resistor 8th which connects the current I _R to the analog ground via a current detection amplifier 9 decides. The current I _R is a factor of GR 2 amplified before it is sent to the subscriber line.

The Voltage at the node UDCO is proportional to the line current. The line current has the same phase as the voltage at the node UDCO on. There is a phase difference between the current Ibat and the voltage UDCO dependent from the load on the line.

In a paging mode, there is an AC load on the line. The signal UDCO will be symmetric around the analog ground, the duty cycle is 50%. When the handset is removed, the load will become a DC load, and the duty cycle of the UDCO signal will be greater than 50%. As the listener changes state, the phase difference between the current Ibat and the voltage UDCO will be changed. The call-disconnect detector 11 detects the zero crossings and detects a change, which turns into a Rufabschaltung.

3 shows that the ibat generator 4 is controlled by an input voltage CREFSC, and its value is proportional to this input voltage, where zero volts equals zero current, and an analog mass yields maximum current. A counter 14 and a SC filter 15 generate a controlling voltage for the Ibat generator.

• – Das SC-Filter verändert die Ausgangsspannung schrittweise nach oben.
• – Das SC-Filter setzt die Ausgangsspannung auf einen Maximalwert.
• – Das SC-Filter verändert die Ausgangsspannung schrittweise nach unten.
• – Das SC-Filter setzt die Ausgangsspannung auf einen Minimalwert.

The SC filter 15 is through the counter 14 which sends signals to the SC filter to increase, decrease or set the output voltage. The counter cycle is divided into the following operating modes:

• - The SC filter gradually changes the output voltage upwards.
• - The SC filter sets the output voltage to a maximum value.
• - The SC filter gradually changes the output voltage downwards.
• - The SC filter sets the output voltage to a minimum value.

each Mode has an output signal for controlling the switched capacitor filter (SC filter) on: RUP, RSET, RDOWN and RRST.

The input clock, 2 Mhz, is counted by the counter 14 divided, so that the counter cycle corresponds to the Rufsignalzyklus. The counter is used as a reference. The outputs from the reference counter 14 , q9-q4, show the position of the call cycle. The paging cycle is controlled by the inputs d2, d1, d0 from a device processor which turns the paging signal on or off.

The call-disconnect detector 11 is used with the outputs q9-q4 of the reference counter 14 and the output from the comparator 10 supplying zero crossings. If the call-disconnect detector has indicated a call-off, the output is set active and passed to the device processor.

4 shows the battery current waveform Ibat, which generates a call signal on the lead wires A and B. The digital signals q9-q4 represent the outputs of the reference counter of the battery power generator. Its purpose is to control the battery current. The signal sync1 is used for the positive zero crossings and sync2 for the negative zero crossings. These signals from the reference counter are used to reset the counters and load the previous counter value into a memory. UDCO is an internal node of the DC loop with its phase relative to the battery current generator being a response to the load of the line. The solid line shows -90 degrees phase and +90 degrees for the dotted line. These lines show the maximum variation of the phase shift. The current Ibat is a reference to measure the zero crossings of the line current.

If the UDCO signal, which corresponds to the line current through the goes through analog mass, a zero crossing is relative to the Reference current Ibat detected. There is a digital zero crossing measurement relative to Ibat. The issues of the reference counter to Ibat are registered when UDCO passes through the analog ground, at both negative and positive zero crossings.

5 shows the call-disconnect detector 11 detail. The output signal ZEROPASS from the comparator 10 is connected to the D flip-flop DFF, which is clocked by a 2 Mhz signal and connected to the inverter INV. The outputs of the inverter and the D flip-flop are connected to a NOR gate and an AND gate, which generate a pulse at positive zero crossing ZPASSPOS and a pulse at the negative zero crossing ZPASSNEG.

The Latches L1 and L2 load the outputs of the reference counter, which the battery current generator controls when the pulse for the positive Zero crossing or the pulse for the negative zero crossing during the current call cycle occur. The phase of the signal UDCO can up to +/- 90 Degree relative to the battery current Ibat be dependent on the line load. The synchronization signal SYNC1 or SYNC2, which is 180 degrees to battery power is charging the exits of the latch L1 in the latch L11 or the outputs of the latch L2 in the latch L22. When the synchronization signal occurs, a new paging cycle is started, and the latches L11 and L22 store the outputs of the reference counter of the previous call cycle for the positive zero crossing or the negative zero crossing. The outputs Latches L11 and L22 are connected to each digital comparator C1 and C2 connected. If the reference counter past the values of the previous call cycle, another one occurs Pulse at the outputs of the digital comparators C1 and C2. The difference of zero crossings between the previous and the current call cycle is determined by the counter CE1 for the positive zero crossings or the counter CE2 for the negative zero crossings measured. The first zero crossing of the current or the previous one Call cycle starts the counter CE1 and the last zero crossing keep the counter CE1 for the positive zero crossings or CE2 for the negative zero crossings at. If the zero crossing difference between the current and the previous call cycle is greater than is a fixed value, the output will indicate a "phase difference", and if If it is lower than the fixed value, it will indicate "no phase difference." The SYNC1 signal clears the counter CE1 and the SYNC2 signal clears the counter CE2 in every call cycle.

During each ring cycle, the zero crossings will be measured relative to the battery current Ibat at both positive and negative zero crossings. It is sufficient that one of these measurements shows a phase difference so that this cycle indicates a phase difference to the counter RT. The outputs of counters CE1 and CE2 are connected to a counter RT. The mode input or mode input of this counter is connected to the output of an RS flip-flop RS1, the R input of the RS flip-flop is connected to the RINGBURSTN signal, which returns the RS flip-flop at the beginning of the Rufsignalfolge when the RS flip-flop is cleared, the qs output of the counter RT goes to a logic "high" level when a predetermined consecutive number of zero crossings with "no phase difference" has been reached. The ringing signal zero crossings are established and the counter RT counts consecutive cycles with "phase difference." When the counter has reached another predetermined value, the output qe of the counter goes to high logic level The output qe is connected to another RS flip-flop RS2 which sets at a high logic level The circuit sends a call-disconnect message to the device processor.

Before the circuit is set in the ringing mode, the RS flip-flops RS1 and RS2 cleared by a RINGBURSTN signal.

While the above description includes numerous details and peculiarities, It should be understood that these are merely illustrative of the present invention are and not as limitations are to be interpreted. Many modifications which are within the scope of the invention as by the attached claims will not be left undefined, will be obvious to professionals.

Claims (6)

A method for detecting call disconnection with a call-disconnect detector, said call-disconnect detector comprising a reference counter ( 14 ) for controlling a battery power generator (Ibat) to generate a paging signal sequence with ringing cycles in a line, the method comprising: detecting zero crossings of a voltage signal (UDCO) proportional to a current on the line, counting a phase difference between zero crossings in a previous one and in a current call cycle relative to outputs (q4-q9) of the reference counter ( 14 ) to generate a phase difference count for the current paging cycle, deciding that the current paging cycle has "no phase difference" when the phase difference count is below a threshold, and deciding that the current paging cycle identifies "phase difference" if the phase difference count is above the threshold is, counting a first predetermined number of consecutive calling cycles with "no phase difference" at the beginning of the call signal sequence, wherein the call signal sequence is established after the predetermined number has been reached, and counting a phase difference number of consecutive calling cycles with "phase difference" after the call signal sequence is established, wherein a Rufabschaltung is detected when the phase difference number reaches a second predetermined number. Device for detecting call disconnection comprising a reference counter ( 14 ) for controlling a battery power generator (Ibat) for generating a paging signal sequence with ringing cycles on a line, a zero-crossing detector ( 10 ) for detecting zero crossings of a voltage signal (UDCO) proportional to a current on the line, a first counter (CE1, CE2) and a second counter (RT), wherein the first counter (CE1, CE2) is configured, a phase difference between zero crossings in a previous and a current paging cycle relative to outputs (q4-q9) of the reference counter ( 14 ) to generate a phase difference count for the current paging cycle, wherein the first counter (CE1, CE2) is further configured to decide that the current paging cycle has "no phase difference" when the phase difference count is below a threshold, and to decide that the current paging cycle has "phase difference" when the phase difference count is above the threshold, the second counter (RT) being configured to count a first predetermined number of consecutive paging cycles with "no phase difference" at the beginning of the paging sequence, wherein after the predetermined number has been reached, the calling signal sequence is established and, after the calling signal sequence is established, to count a phase difference number of consecutive calling cycles with "phase difference", wherein a call cancellation is detected when the phase difference number reaches a second predetermined number. Apparatus according to claim 2, wherein the zero-crossing detector is controlled by a comparator circuit ( 10 ) is formed with a negative input connected to ground, a positive input connected to the voltage signal, and an output connected to a logic (DFF), the logic being designed so that a first pulse at positive zero crossings of the zero crossings for driving a memory ( L1, L11) such that the outputs (q4-q9) of the reference counter ( 14 ) in the memory (L1, L11) is stored, when the first pulse is generated, wherein the memory (L1, L11) is configured, the outputs (q4-q9) of the reference counter ( 14 ) of the previous and the current call cycle, the device being designed such that when the outputs (q4-q9) of the reference counter ( 14 ) pass a value of the outputs (q4-q9) of the previous ring cycle stored in the memory, a second pulse is generated, the first pulse and the second pulse being a first sub-counter (CE1) of the first counter (CE1, CE2) for counting a first sub-counter (CE1) for generating a first signal indicative of whether the first phase difference has reached a threshold, the logic being further configured in that a third pulse at negative zero crossings of the zero crossings for driving a further memory (L2, L22) such that the outputs (q4-q9) of the reference counter ( 14 ) are stored in the further memory (L2, L22) when the third pulse is generated, with the further memory being configured, the outputs (q4-q9) of the reference counter ( 14 ) of the previous and the current call cycle, the device being designed in such a way that when the outputs (q4-q9) of the reference counter ( 14 ) pass a value of the outputs (q4-q9) of the previous call cycle stored in the further memory, a fourth pulse is generated, the third pulse and the fourth pulse to a second subcounter (CE2) of the first counter (CE1, CE2) for counting a second phase difference between negative zero crossings in the preceding and the present call cycle, wherein the second sub-counter (CE2) is configured to generate a second signal indicative of whether the second phase difference has reached a threshold value, the first signal and second signal are supplied to the second counter (RT), wherein the device is configured such that the mode of the second counter (RT) at the beginning of the Rufsignalfolge is deleted, and the mode of the counter is set when the Rufsignalfolge is established. Apparatus according to claim 3, wherein said logic comprises a D-type flip-flop (DFF), an inverter (INV), an AND-gate and a NOR-gate, the output of said comparator circuit (DFF). 10 ) is connected to an input of the D flip-flop (DFF) and an input of the inverter (INV), wherein a clock input of the D flip-flop (DFF) is connected to a 2 Mhz signal, wherein an output of the inverter (INV) with a first input of an AND gate and a second input of a NOR gate and an output of the D flip-flop to a second input of the AND gate and a second input of the NOR gate is connected such that the first pulse as a Output of the NOR gate is generated and the third pulse is generated as an output of the AND gate, wherein the first memory (L1, L11) comprises a first latch clocked by the first pulse (L1) and the second memory (L2, L22 ) comprises a latch (L2) clocked by the third pulse. The apparatus of any of claims 2-4, wherein the first memory comprises a first latch (L1) and a second latch (L11), the second memory comprising a third latch (L2) and a fourth latch (L22), the logic a first digital comparator (C1) and a second digital comparator (C2), the logic being arranged to store the outputs (q4-q9) in the first latch (L1) when the first pulse is generated Outputs (q4-q9) are stored in the third latch (L2) when the third pulse is generated, the outputs stored in the first latch (L1) are transferred to the second latch (L11) and those in the third latch (L2 ) are transferred to the fourth latch (L22) to store the outputs (q4-q9) of the reference counter (14) of the previous call cycle, outputs of the third latch (L11) being coupled to first inputs of the first digital comparator (C1). are connected and outputs of the fourth latch (L22) are connected to first inputs of the second digital comparator (C2), the outputs (q4-q9) of the reference counter ( 14 ) are connected to second inputs of the first digital comparator (C1) and the second digital comparator (C2), wherein the first digital comparator (C1) and the second digital comparator (C2) are configured to supply the second pulse and the fourth pulse, respectively produce. Device according to one of claims 2-5, wherein a clock input of the second counter (RT) is connected to a 2 Mhz signal, wherein a mode input of the second counter (RT) is connected to an output of an RS flip-flop (R1) an R input of the RS flip-flop (RS1) is connected to a RINGBURSTN signal which resets the RS flip-flop at the beginning of the paging signal sequence, an output (qs) of the second counter (RT) being connected to an S input of the RS Flip-flop (RS1) is connected, wherein the output of the second counter (RT) is configured to go to a high logic level, and the second counter (RT) is configured such that a mode of the second counter is changed when the signal sequence is established, wherein a further output (qe) of the second counter is configured to go to a high logic level when the second predetermined number is reached, the further output (qe) being connected to an input of an AND gate, a second input the AND gate is connected to an output of the RS flip-flop (RS1), wherein an output of the AND gate is connected to an S input of another RS flip-flop (RS2), wherein an A input of the further RS flip-flop (RS2) is connected to the RINGBURSTN signal for resetting the further RS flip-flop (RS2) at the beginning of the paging signal sequence, wherein an output of the further RS flip-flop (RS2) is configured to go to a high logic level when the paging is detected.