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Description  |
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TECHNICAL FIELD OF THE INVENTION
The present invention relates to a combination ringing and message-waiting
lamp (Ring/MWL) power generator for use, in particular, in a private
branch exchange (PBX) switching machine.
BACKGROUND OF THE INVENTION
As is known in the art, in applications such as in a private branch
exchange (PBX) switching machine, there is a need to supply power to
ringing circuits in analog telephones connected to the switch and there is
a need to supply power to message-waiting lamps connected to the analog
telephones which are, in turn, connected to the switch. The voltage
required for the ringing circuit is, for example, an 85 V rms sine wave
having an amplitude between 0 V and 120 V and the voltage required for
illuminating a neon message waiting light is, for example, about -150 V
dc. In practice, the maximum power delivered to these circuits is quite
high, being approximately 18 Watts during a ringing interval and being
approximately 50 Watts during a message-waiting lamp interval. Unless the
power efficiency of the power generators are high, power generators of
this type can dissipate a large amount of heat and power. Further, such a
large heat and power dissipation may decrease the reliability of the power
generators which are typically shared critical resources in the PBX.
In light of the above, there is a need in the art for a power generator for
use in providing power to ringing circuits and message-waiting lamps
(Ring/MWL) which reduces power dissipation.
SUMMARY OF THE INVENTION
Advantageously, embodiments of the present invention are Ring/MWL power
generators which provide a power waveform for applying power to ringing
circuits and message-waiting lamps and which power generator reduces power
dissipation. In particular, an embodiment of the inventive power generator
comprises: (a) means for generating a low-level signal representing the
power waveform and for generating a timing and control signal indicative
of various portions of the low-level analog signal; (b) means, responsive
to the timing and control signal, for altering the output of a
high-voltage power supply; and (c) means, responsive to the low-level
signal and the output of the high-voltage power supply, for amplifying the
low-level signal to produce the power waveform.
Advantageously, embodiments of the present invention reduce power
dissipation in a power amplifier and, thereby, increase the circuit's
reliability. Further, embodiments of the present invention reduce power
dissipation in the high-voltage power supply and, thereby, increase the
supply's reliability. Still further, embodiments of the present invention
eliminate a need for large and expensive heatsinks to cool power
transistors and decrease the cost of the Ring/MWL power generator. Yet
still further, when used in conjunction with a PBX, embodiments of the
present invention reduce power loading on a PBX system power supply as
compared with conventional designs and help alleviate temperature rise
inside the PBX cabinet.
BRIEF DESCRIPTION OF THE FIGURE
FIG. 1 shows a high-power, Ring/MWL composite, output signal waveform
produced by embodiments of the present invention;
FIG. 2 shows a block diagram of an embodiment of the present invention; and
FIG. 3 shows a block diagram of a preferred embodiment of the present
invention.
DETAILED DESCRIPTION
FIG. 1 shows a high-power, Ring/MWL composite, output signal waveform
produced by embodiments of the present invention. As shown in FIG. 1, ring
and message-waiting lamp (Ring/MWL) composite signal 200 is shown having
sinusoidal ring intervals 100 and 110 and dc MWL interval 120. Further, as
shown in FIG. 1, V.sub.a is the voltage produced by a dc power supply
during ring intervals 100 and 110. V.sub.b is the power supply voltage
used in illuminating a typical neon message waiting light for an analog
telephone, voltage 150 is -48 V dc with respect to ground, and signals 100
and 110 are 85 V rms sinusoidal waveforms being 0 V to .+-.120 V peak. As
one can readily appreciate from FIG. 1, P.sub.d is the power saved during
MWL interval 120 by embodiments of the present invention by reducing the
voltage from V.sub.a to V.sub.b. Although FIG. 1 shows a composite signal
wherein a ring interval is followed by a message-waiting lamp interval
which is followed, in turn, by another ring interval, those of ordinary
skill in the art understand that this signal is merely illustrative of
signals which are produced by embodiments of the invention and that other
signals may be produced such as, for example, sequences of a ring interval
and a no-ring interval, sequences of a message-waiting lamp interval and a
no-message-waiting lamp interval, and so forth.
FIG. 2 shows a block diagram of an embodiment of the present invention. As
shown in FIG. 2, Ring/MWL waveform generator 300 generates two wave forms,
Ring/MWL waveform 305 which is applied as an input to power amplifier 310
and Ring/MWL timing waveform 307 which is applied as an input to power
supply output control and monitor circuit 320. As is known in the art,
Ring/MWL waveform 305 is a small signal version of a composite Ring/MWL
output waveform. Ring/MWL timing waveform 307 is a control signal which
indicates the interval, whether ringing or MWL, that is represented in
small signal Ring/MWL waveform 305. Power supply output control and
monitor circuit 320, in response to Ring/MWL timing waveform 307 and
feedback signal 309, produces power supply control signal 3 13. Power
supply control signal 3 13 is applied as input to power supply 330. In
response to power supply control signal 3 13, power supply produces
variable tracking power supply voltages 323 which is applied as input to
power amplifier 310.
In one embodiment of the present invention, power output control and
monitor 320 is a differential amplifier and ring/MWL timing waveform 307
is a reference voltage which is compared with feedback signal 309. Output
error signal 3 13 from power output and control monitor 320 is used in a
manner which is well known in the art to regulate the output of power
supply 330.
FIG. 1 shows variable tracking power supply 323. As one can appreciate from
FIG. 1, variable tracking power supply waveform 323 has a larger amplitude
during ringing intervals 100 and 110 than it has during MWL interval 120.
This reduces the power dissipation during MWL interval 120 described
above.
Lastly, as can be readily understood by those of ordinary skill in the art,
with reference to FIG. 2, in response to variable tracking power supply
waveform 323 and Ring/MWL waveform 305, power amplifier 310 produces
Ring/MWL composite signal 200 which is used, for example, to drive analog
telephones connected to a PBX. Thus, in accordance with the present
invention, variable tracking power supply waveform 323, in sync with Ring
and MWL time intervals, removes unnecessary voltage "headroom" that would
otherwise be dissipated as wasted power and heat in power amplifier 310
(referring to P.sub.d shown in FIG. 1).
Thus, in summary, an embodiment of the inventive Ring/MWL generator
produces a timing signal to vary and synchronously control the output
voltage of a power supply which drives a power amplifier. During a ring
interval, the power supply produces its highest output-voltage (see
voltage V.sub.a of FIG. 1) to generate a high voltage Ring output signal.
However, during an MWL interval, the power supply produces a lower voltage
(voltage V.sub.b of FIG. 1 ) to generate a lower voltage MWL signal.
Embodiments of the present invention reduce power dissipation in the power
amplifier substantially. For example, in a conventional design utilizing a
fixed voltage power supply, a surplus "headroom" of 30 volts (the
difference between V.sub.a and V.sub.b in FIG. 1) is usually placed on the
power amplifier during an MWL interval. Such a surplus results in 15 Watts
of power dissipation in the power amplifier for a 0.5 Amp load current.
Utilizing an embodiment of the present invention which provides a variable
tracking power supply which can drop the "headroom" voltage to 1 Volt or
less, power dissipation is reduced to less than 0.5 Watts, a 30:1
reduction in power dissipation.
FIG. 3 shows a block diagram of a preferred embodiment of the present
invention. As shown in FIG. 3, .mu.P 400 produces two signals, digitized
composite signal 410 and power supply control signal 440 (PSCTRL 440), to
regulate the operation of the preferred embodiment. Digitized composite
signal 410 is a digitized representation of a power waveform such as, for
example, the composite ringing and message waiting signal shown in FIG. 1.
Digitized composite signal 410 is produced by a firmware algorithm that
resides in a read-only memory (ROM) of .mu.P 400. The algorithm utilizes a
look-up table of values to generate 6-bit words where each 6-bit word
corresponds to a specific analog voltage level once the digital word is
converted into an analog signal. In accordance with the preferred
embodiment, the conversion is performed via 6-bit digital-to-analog (D/A)
converter 420. In accordance with the algorithm, each word in the look-up
table is scanned to produce a digital sequence that will generate
low-level analog signal 430 from D/A converter 420 which comprises a 4 V
rms sine wave and a -4.8 V dc signal (low-level analog signal 430 of FIG.
3 corresponds to Ring/MWL waveform 305 of FIG. 2). Low-level analog signal
430 output by D/A converter 420 does not have enough voltage or current to
directly drive a ringer and a message-waiting lamp of a telephone.
Therefore, Class "B" power amplifier 490 is utilized to boost low-level
analog signal 430 to the power levels needed to drive the loads. In
particular, amplified Ring/MWL composite signal 200 comprises an 85 V rms,
20 Hz sine wave for ringing the telephones and a -100 V dc level for
driving neon message-waiting lamps. In one particular embodiment of the
preferred embodiment, Class "B" power amplifier 490 is an electrically
floating source which receives a -48 V dc bias from a -48 V dc power
supply associated with a PBX. In this case, composite Ring/MWL composite
signal 200 is comprised of an 85 V rms sine wave (biased by -48 V dc) and
a -148 V dc level. Embodiments of .mu.P 400, D/A converter 420, and power
amplifier 490 are well known to those of ordinary skill in the art.
As further shown in FIG. 3, .mu.P 400 produces power supply control signal
440 which is applied as input to high-voltage power supply 450.
High-voltage power supply 450 provides voltage and current to energize
power amplifier 490 and the load. High-voltage power supply 450 produces
two output levels, depending on whether power amplifier 490 is ringing
telephones or illuminating message-waiting lamps. Power amplifier 490
requires a higher voltage (.+-.125 V de) to ring the telephones than it
does to illuminate the lamps (.+-.105 V dc). In one particular embodiment
of the preferred embodiment, a negative flyback DC-to-DC converter is used
to generate these voltages from PBX -48 dc power supply 460.
PSCTRL signal 440 produced by .mu.P 400 is a two-state digital signal which
controls the output voltage from high-voltage power supply 450. PSCTRL 440
is generated by a firmware algorithm in .mu.P 400 and it is synchronized
with digitized composite signal 410 applied as input to D/A converter 420.
At the beginning of a ringing interval, .mu.P 400 sets the state of PSCTRL
440 to a level that will cause high-voltage power supply 450 to produce
.+-.125 V dc. At the beginning of a message-waiting interval, .mu.P 400
changes the state of PSCTRL 440 to a level that will cause high-voltage
power supply 450 to produce .+-.105 V dc. High voltage power supply 450 of
FIG. 3 is a variable power supply and includes power output control and
monitor 320 and power supply 330 shown in FIG. 2. This cycle of events
will repeat at the start of the next ringing interval. As a result, and in
accordance with the present invention, PSCTRL 440 enables high-voltage
power supply 450 to deliver the minimum "headroom" voltage needed by power
amplifier 490 to drive each load.
Those skilled in the art will recognize that the foregoing description has
been presented for the sake of illustration and description only. As such,
it is not intended to be exhaustive or to limit the invention to the
precise form disclosed. For example, modifications and variations are
possible in light of the above teaching which are considered to be within
the spirit of the present invention. In particular, although the
above-described embodiment utilized a microprocessor-based controller and
waveform generator, embodiments of the present invention can also be
embodied utilizing analog circuits exclusively. For example, the
microprocessor-based waveform generator can be replaced with well known
analog sine wave and voltage ramp generator circuits. The outputs from
these circuits can be combined, via an analog summing circuit, to produce
the low-level composite waveform that is applied to the power amplifier.
Further, the PSCTRL signal can be derived from the output of the voltage
ramp generator. Thus, in light of this, it is to be understood that the
claims appended hereto are intended to cover all such modification and
variations which fall within the true scope and spirit of the invention.
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