Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
This specification has been divided from a patent
application by Ernst August Munter with Serial No. 396,210 and filed on
12 February, 1982.
The invention relates generally to telephone systems and
more particularly to a digital circuit and method for the detection of
call progress tones therein.
Background of the Invention
In a telephone system, call progress tones are used for
indicating to the user the status of his call. Typical signals are
labelled audible ringing, dial tone, busy tone, and reorder tone. In the
conventional system~ these tones are detectable by the user of the system.
However, the creation of private networks has resulted in the need for
circuitry capable of recognizing these call progress tones since these may
not be available at the call originating end of such networks. In
addition, since these tones are the basis for billing procedures on these
networks, the detection circuits need to be accurate and fast so that the
billing period is accurately identified. Furthermore, the proliferation
of digital switching systems has created the additional requirement that
any such detection circuitry be able to operate directly on pulse code
modulated (PCM) signals.
Unfortunately, the North American telephone network does not
have a precise tone plan that has been universally adopted. There is
therefore a considerable variation in the tone frequencies and cadence
employed by various telephone utilities. A comprehensive listing of the
various tones may be found in the publication entitled "Notes on the
Network" published in 1980 by the American Telephone and Telegraph Company
at pages 110 to 119. The most common of the call progress tones are dial
;2~
tone, audible ringing tone9 busy tone, ard reorder tone. The precise tone
plan specification for the North American network defines these tones as
follows, dial tone is a continuous tone having frequencies of 350 and
440 Hz at a level of -13dbm. Audible ringing tone is defined as
comprising frequencies of 440 and 480 Hz at a level of -19 dbm and a
cadence of 2 seconds ON and 4 seconds OFF. Busy tone is defined as having
frequency components of 480 and ~20 Hz at a level of -24 dbm and a cadence
of half a second ON and half a second OFF, whereas reorder tone contains
the same frequency components at a comparable level but with a cadence of
0.25 of a second ON and 0.25 of a second OFF. Other frequencies and
levels are generated by older equipment which does not follow the precise
tone plan; these tones are either formed as dual frequency tones or as
amplitude modulated signals where a higher frequency is modulated by a
lower frequency.
It is therefore desired to provide a circuit for the
automatic recognition and identification of call progress tones on the
telephone network which is accurate, reliable, fast and economical~ It is
further desired to provide such a circuit that operates on digital
signals.
In the past, there has been a wide variety of methods
proposed for solving this problem including digital filtering and spectral
analysis of the signals. More recently, there have been proposals that
provide somewhat simpler circuitry to recognize the basic call progress
tones. The first of these is known as the energy system and is based on
the recognition of energy bursts in the signal, whereby counting the
number of "tone bursts" of the signal in the specified period indicates
the identity of the tone. Effectively, this method relies on the
detection of the cadence of the signal. A second method, relies on the
incidence of zero crossings by the signal being detected. However, the
known methods of detection have been found to be inadequate especially in
the identification of dual-frequency tones.
The Invention
The invention provides a circuit for the detection and
identification of call progress tones appearing on telephone lines and
which is both fast and reliable as well as being accurate. The circuit of
the invention operates on pulse code modulatPd signals and is therefore
ideally suited for use in contemporary digital systems such as that
described in U.S. patent No. 4,213,201 entitled "Modular Time Division
Switching System" and assigned to the present assignee. The tone
detection service circuit of the invention operates on the PCM bit stream
to identify call progress tones such as audible ringing, busy tone,
reorder tone, dial tone, as well as voice and silence periods.
The circuit performs a frequency and envelope analysis on
the digital signal received from a terminating trunk or the like. The
detector is based on the observation that when dual frequency components
exist in a tone, the waveform of the tone is complicated and has an
envelope which represents the difference frequency between the two
frequencies of the tone. The higher frequency component is recognizable
through the amplitude modulated peaks, whereas the envelope frequency when
subtracted from the higher frequency results in the lower frequency
component.
In accordance with the invention there is provided a first
means for measurirg the level of the tone which is linearized and
normalized to a 5 bit PCM signal. A second means is responsive to the
normalized signal for determining the higher frequency component of -the
tone by counting the number of zero crossings in a predetermined period.
A third means is also responsive to the normalized signal for determining
the envelope frequency of the tone. The composite results available from
the first, second and third means represent the identity of the call
progress tone being analyzed. A translation circuit is responsive to the
composite results for providing a signal which represents the identity of
the call progress tone. This signal may then be applied to a suitably
programmed microprocessor for further processing and cadence evaluation.
From another aspect, the invention provides a method for
determining the identity of a signal appearing on a telephone line in a
telephone system. The input signal is linearized and normalized to
provide a 5 bit PCM signal comprising a 4 bit magnitude signal and a sign
bit. The higher frequency component of the signal is then determined by
counting the incidence of zero level traversals by the linearized signal.
Concurrently, the envelope frequency of the signal is determined. The
composite results obtained by measuring the level of the signal,
determining the higher frequency component signal, and determining the
envelope frequency of the signal determine the identity of the PCM tone
signal appearing on the telephone line. The identity of the signal may be
obtained by translating the composite results to provide a single signal
which identifies the signal appearing on the telephone line as a call
progress tone or voice or silence. The cadence of the signa1 appearing on
the telephone line may then be determined by generating and evaluating a
contiguous plurality of the single signals.
In accordance with a further aspect of the invention there
is provided a novel circuit and method for detecting the envelope of a
signal. A normalized ard linearized PCM signal is rectified and applied
to a threshold circuit having lower and upper reference thresholds. The
former is at a level above the zero base whereas the latter is at a level
lower than the maximum amplitude of the envelope being detected~ Since
the input signal exhibits an envelope characteristic the output of the
threshold memory is a chopped pattern. The chopped signal is then filtered
through a threshold filter circuit which acts as a window circuit to
integrate the chopped signal thereby creating a square wave having a
frequency corresponding to that of the envelope frequency. The threshold
filter circuit includes a majority logic circuit responsive to the chopped
signal for enabling a counter circuit which provides an output signal
corresponding to the envelope frequency.
In accordance with a still further aspect of the inventiorl,
there is provided a digital automatic gain control circuit responsive to
companded pulse code modulated signals for providing linearized and
normalized PCM signals. The input PCM signals are translated to linear
PCM signals in a read-only-memory (ROM) which contains a plurality of
pages each representing a different loss level for the input signals. A
control circuit is responsive to the linear PCM signals to vary the ROM
page address until the output linear PCM signal has been normalized to a
predetermined level.
An example embodiment of the invention will now be described
in conjunction with the drawings in which:
Figure 1 is a block circuit diagram of a digital tone
detector in accordance with the invention;
Figure 2a is a block circuit diagram of the AGC circuit
shown in figure l;
Figure 2b is a transfer charcteristic of the circuit shown
in figure 2a;
Figure 3d is a block circuit diagram of the Z~count detector
shown in figure 1;
Figure 3b shows a waveform illustrating the operation of the
circuit of figure 3a;
Figure ~a is a block circuit diagram of the envelope
detector shown in figure 2a;
Figure 4b illustrates a plurality of waveforms taken at
various points in the circuit of figure 4a;
Fiyure 5 is a block circuit diagram of the evaluation logic
circuit shown in figure l;
Figure 6 is a translation diagram; and
Figure 7 is a block diagram of a multiple channel tone
detector in accordance with the invention.
Figure 1 illustrates a peripheral module of a fully digital
telephone switching system such as may be used in the above referenced
U.S. patent No. 4,213,201. A peripheral processor 10 of the peripheral
module communicates with the switching system via a transmission facility
11 and with peripheral or service circuits via a peripheral bus 12. A
digital tone detector 13 is shown to comprise an automatic gain circuit
(AGC) 14, a zero count detector 15, an envelope detector 16, an evaluation
logic circuit 17 and a timing generator 180
In operation, the peripheral processor 10 receives PCM
signals on transmission facility 11 and applies the signal to the tone
detector 13 via the peripheral bus 12 (RPCM). The tone detector 13
manipulates the received PCM signals and provides the processor 10 with
the identity (XDAT) of the received signals. The peripheral processor ~0
verifies the identity of the signals by performing a cadence check and
transmits the required information to the central processor of the
switching system on the transmission facility 11. As described in the
priorly referenced patent9 the processor 10 is adapted to receive and
transmit 32 channels of time divided PCM information. Two of these
channels are used for control information whereas the remainder serve to
handle 30 channels of data. Hence, the tone detector 13 may be used to
detect the identity ot tones appearing in up to 30 different channels.
Since the detection of tones appearing on thirty channels or
trunks, is rnerely a question of performing the same functions 30 times per
frame, the invention will be first described in relation to the detection
of a tone signal on one channel. Also, the embodiment of the invention
described herein may be realized using commercially available
off-the-shelf components.
Figure 2a of the drawings illustrates a fully digital
automatic gain circuit (AGC) for use in the tone detector shown in figure
1, whereas figure 2b illustrates the transfer characteristic for the
circuit of figure 2a. A read-only-memory (ROM) 20 is a linearizing
circuit providing adjustable loss for the input PCM signal. The magnitude
portion (7 bits) of the input signal is linearized to a 4-bit signal
whereas the sign bit of the input signal is made to appear at the output
of the AGC circuit unaltered. The output signal of the AGC circuit
therefore provides a 5 bit linear PCM signal.
The circuit of figure 2a is basically a digital level meter
and an automatic gain control circuit whose function is to provide a
standard size signal for the zero count circuit and envelope detector
circuits. The level of the input signal corresponds to the page address
and is available at the output of register 25. The ROM 2n provides for
a range of approximately 27db of loss divided into 16 increments of 1.7db
each. The memory is therefore divided into 16 pages of 128 levels each.
The transfer characteristic of figure 2b shows that an input
signal having a level of from -10 to -37dbmo will be normalized to an
output signal having a level of approximately -43dbmx. Of course9 it
should be understood that the range of these levels is arbitrary and may
be varied depending on the expected characteristics of the input PCM
signal and the required level of the linear PCM output signal. This may
be accomplished simply by providing a ROM containing the appropriate
translation data.
The linearizing and loss function of ROM 20 is controlled by
an AND gate 21, a damping register 22, a page address controller 23, and
up/down control logic 24. The page controller 23 may simply be an up/down
counter adapted to provide a 4 bit address at its output. The circuit is
clocked at the frame rate (8 KHz) and is enabled by up/down signals from
control logic 24. As the count of the page address controller 23 is
increased, the new address selects a page of the ROM which provides
increased loss to the input signal and conversely, counting down decreases
the loss applied to the input signal.
If the input PCM signal exceeds the signal size expected for
it (the selected page of ROM), the output of the ROM will be Hexadecimal
'F' (all ones). This state will be detected by NAND gate 21 and through
damping register 22 will cause the up/down control logic to provide an
up-count signal to the page address controller 23 thereby increasing the
address to the ROM by one count. If the input PCM signal does not exceed
the signal expected for i~, the 4 bit magnitude word will not be all ones
and the page address will remain constant. However, every 20
milliseconds, a decay signal applied to the control logic 24 will cause
the counter 23 to be decremented if the signal at the output of NAND gate
21 is a zero. This allows the circuit to track decaying siynals. In this
way, the AGC circuit will normalize any input signal within the range of
the circuit by applying more loss to a larger signal and will track
decaying signals by decreasing the loss one step every 20 milliseconds.
Input signals having a level higher than the range permittecl by the
circuit will be clipped. Also, short noise pulses are rejected by the AGC
circuit by virtue of the inherent controlled attack time (l3
db/millisecond) of the circuit.
Since the circuit of figure 2a functions as a peak reading
voltmeter with a fast attack and slow decay time, noise signals riding on
the input signal can result in sporadic high level readings. This may be
prevented by using a damping register 22 for storing one or more One
signals provided at the output of NAND gate 21 until a plurality (e.g. 4)
of these signals have occurred. Therefore, the signal at the output of
the gate 21 will cause the control logic to issue an up-count signal only
if 4 consecutive all ones condition have occurred. If not, the register
is simply reset~ Of course, the register 22 may be designed to store any
number of "one" signals from gate 21, depending on the expected level of
noise. In addition to supplying a 5 bit PCM signal which is the
linearized and normalized version of the input signal, the AGC circuit of
figure 2a also provides the last count or page address as a measure of the
level of the input signal to the evaluation logic.
Figures 3a and 3b of the drawings illustrate the circuit and
operation of Z-count circuit 15. The circuit counts the number of zero
crossings traversed by the 5-bit linear PCM signal from the AGC circuit of
figure 2a in a lO millisecond period. The count is made by counter
circuit 30. At the beginning of a 10 millisecond period, the count 30 is
cleared and the counter is incremented by one count each time that a zero
crossing is detected. The incoming signal is compared to hysteresis
threshold ~ ~2) by comparator 31 and the sign bit from the previous frame
is stored in polarity memory 32. The sign bit from the previous frame is
compared to the new sign bit by the exclusive OR gate 33 which enables
comparator 31 if the new and previous sign bits are different. Therefore,
the counter will be incremented by the output of gate 34 if the new and
previous sign bits are different and if the threshold levels are exceeded.
Counter 30 provides a 6 bit parallel output signal for use by the
evaluation logic. This signal or Z-count corresponds approximately to the
higher frequency of a dual frequency tone or the carrier frequency of an
amplitude modulated tone signal.
Figures 4a and 4b illustrate the circuit and operation of a
digital envelo?e detector in accordance with the invention. The envelope
detector is used to determine the frequency of the envelope of a dual
frequency tone and provides an output signal every 100 milliseconds. The
operation of the ~nvelope detector is based on the observation tha-t the
amplitude envelope of a two frequency signal with approximately equal
level of the two frequencies represents the difference frequency. In
effect, the signal looks like an amplitude modulated signal, with the
modulation frequency heing the difference frequency.
Waveform A of figure 4b is the analog representation of the
linear PCM signal appearing at the input of the circuit. In order to
detect the envelope of the signal, the 5 bit POM signal is first
rec~ified. This is achieved simply by ignoring the sign bit as shown in
waveform B of tigure 4b. The rectified signal is applied to a comparator
40 having low and high reference threshold levels that give a Schrnitt
trigger action. That is, high signals must reach a low threshold of less
than a predetermined amount (e.g. 4) before being considered d low and low
signals must reach a high threshold of greater than a second predetermined
amount (e.g~ 9) before being considered a high signal. This comparison has
the effect of truncating the input signal to provide a chopped signal as
shown in waveform C of figure 4b. It has been found tha-t differential
thresholds of approximately one half full scale of the input signal
provide satisfactory results.
The output of comparator 40 is fed to a threshold filter
comprised of a threshold register 41 and a ROM 42 to generate a square
waveform (fig. 4b, waveform D) having a frequency corresponding to the
envelope frequency of the input signal. Nine consecutive results from the
comparator 40 are stored in T-word register 41 which may conveniently be
a serial to parallel converter. On the occurrence of the ninth
comparison, the output of the register 41 is presented as an address to
ROM 42 which operates as a majority logic circuit. That is, the ROM
output is a one if three or more of its nine inputs are ones. The
previous ROM output is stored in a flip-flop 43 and is compared with the
new value by the exclusive-OR gate 44 which functions to increase the
count of counter 45 if the previous and new values are different. Every
100 milliseconds, the envelope or E-count is made available to the
evaluation logic and the envelope detector circuit is reset to indicate
the beginning of the next 100 millisecond window~ As discussed above, the
envelope frequency measured over a fixed window gives a number
proportional to the difference in frequencies contained in a dual
frequency tone.
The information available from the AGC circuit, the Z-count
circuit, and the envelope detector circuit characterizes the received PCM
signal with respect to level, zero crossing count, and envelope frequency
count. These characterizations comprise a total of 15 bits which are
available at different time periods. The level signal from the AGC circuit
is a 4 bit signal generated every 125 ~sec., the Z-count signal from
the zero crossing circuit is a 6 bit signal available every 10
milliseconds whereas the envelope frequency count from the envelope
detector is a 5 bit signal available every 100 milliseconds. Since each
audible tone comprises a range of characterizations, the 15 bits of
information comprising each characterization may be compressed to provide
a more easily handled signal. Figure 5 illustrates an evaluation logic
circuit which operates on the raw data generated by the above detector and
counter circuits to produce a code that indicates the type of signal or
tone currently being received. Each completed count, as it is read from
the respective circuit is presented to the compression ROM 50 which scales
it down in order to be represented by a smaller number of bits by
excluding invalid (out-of-range) codes for the tones expected for
decoding, and combining equivalent values or counts into single codes.
The level, Z-count, and E-count outputs are compressed to 3, 4, and 4 bits
respectively in ROM 50 and are respectively latched into registers 51, 52,
and 53. All of this data appearing at the output of registers 51 to 53 is
o~
presented in parallel to an evaluation ROM 5~. The evaluation ROM is
mapped so that a code corresponding to the signal represented by the raw
data appears at the output of the ROM. The same code is used to indicate
a tone over its expected range of level, Z-count, and envelope count
taking into accunt network loss, frequency tolerances, and edge-effects of
the windowing process. This code may then be gated to the peripheral
processor on the XDAT link of the peripheral bus at the appropriate time.
The output signal from the evaluation ROM indicates the
identity of the input PCM signal to the tone detector. However, if the
detected level is less than -35dbm (lowest level detectable by the AGC)
then the output code indicates that the line being measured is silent. In
fact, if the measured level corresponds to page O or 15 of the ROM 209 the
signal is considered to be of an indeterminate level and therefore outside
its normal range. Various other codes indicate the type of signal being
detected, such as audible ringing, busy/reorder tone, or dial tone. In
addition, if the signal being detected cannot be qualified as a
recognizable tone, the output signal from the evaluation ROM indicates
that it is a voice signal. It should also be recognized that since the
Z-count and envelope detector circuits operate during real time windows
(10 ms and 100 ms respectively) their frequency resolution is
approximately 50 Hz and 5 Hz respectively. However, this is of no
consequence since the tones being detected are separated in frequency by
more than the frequency resolution of this circuitO
Figure 6 illustrates a translation diagram or map for the
evaluation ROM 54. Audible ringing is detected if the Z-count corresponds
to a frequency between 300 Hz and 550 Hz, the envelope frequency is
between 25 Hz and 70 Hz, and the level is within range. ~ial tone is
detected if the Z-count corresponds to a frequency between 300 Hz and 500
Hz, the envelope frequency is between 75 Hz and 100 Hz and the level is
within rangeO Busy-r~order tone is detected if the Z-count corresponds to
a frequency between 350 Hz and 650 Hz, the envelope frequency is between
105 Hz and 165 Hz, and the level is acceptable. As can be seen from
figure 6, the invention provides a three-dimensional characterization for
a tone.
It should be recognized that other tones may be detected.
All expected detectable tones may be classified, and a look-up table
prepared which maps all acceptable detector combinations into -tone
identities as above. All unclassified combinations exceeding a minimum
threshold may be considered as speech and mapped into a single code.
Similarly, all signals below a minimum threshold classify the channel as
quiet.
The peripheral processor 10 receives the identification code
from the evaluation ROM 54 and performs verification of the identity of
the tone by operating on the signals in real-time to ensure that the
identities being received are consistent with the expected cadence for the
tones. That is, if successive codes are received for audible ringing, it
is expected that the tone will display a 2 second ON, 4 second OFF
characteristic. Similarly, the processor verifies that a busy tone code
exhibits the characteristic 0.5 seconds ON and 0,5 seconds OFF cadence and
that a dial tone identification is a continuous tone. Cadence
determination is especially useful in cases where the characterizations
provided by the AGC, Z-count and envelope detector circuits locate the
detected signal at the boundaries of the maps shown in figure 6 or when it
is desired to differentiate between busy tone and reorder tone.
14
A signal representing the identity of a tone appearing on
any one channel is available at the output of the evaluation ROM 54 every
100 milliseconds. However, intermediate results from the AGC circui-t 14
and the Z-count circuit 15 may be made available from the level register
51 and Z-count register 52 by enabliny them at their respective intervals
of 125 ~sec. and 10 milliseconds~ Similarly, it may be desirable, to
obtain the raw data from the AGC, the Z-count circuit and the envelope
detector for maintenance purposes. This data may conveniently be obtained
at the input of the compression ROM 50.
Figure 7 is a block circuit diagram illustrating how the
tone detector of figure 2a may be connected for multiple channel service.
As mentioned above, the tone detector circuit communicates with the
processor of the peripheral module via the peripheral bus on a time
division basis. The communication link comprises 32 time divided
channels, two of which are used for control signals. Therefore, the tone
detector may be employed to serve 30 channels each of which is subdivided
into ten bit times.
Since the tone detector operates in real time on voice
frequency signals, the time period required to identify a tone is much
longer than the period of a frame (125 ~sec). Therefore, the progressive
results of the detection must be stored during the inter-frame periods.
This is achieved by using a pair of internal buses C-bus and B-bus, a pair
of memories 70 and 71 and a register 72 which is a serial in/parallel out
and parallel in/serial out device. Generally, the register 72 is used for
the bidirectional transfer of information from the peripheral bus to
memory 70 via the C-bus. The B-bus is used for the bidirectional transfer
of inter-frame progressive results between the memory 71 and the tone
detector circuitry. The 10 bit clock periods of each channel are used to
control -these bidirectional transFers of information.
The timing signals necessary to the operation of the tone
detector may be derived from clock and enable signals on the peripheral
bus by timing and address generator circuit 73. The remainder of the
circuits of figure 7 are identical to those illustrated in figures 2 to 5
with the addition of necessary timing signals to provide the time shared
operation of the tone detector.
There has been described a tone detector for call progress
tones which is fully digital and which is fast and accurate as well being
suitable to serve a large number of PCM channels in a time-division
system. The circuit described herein is ideally suited to the detection
of a wide range of tones and the necessary modifications to that end may
be implemented without departing from the spirit of the invention.
16
