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| United States Patent | 4818891 |
| Link to this page | http://www.wikipatents.com/4818891.html |
| Inventor(s) | Drinkwater; Don L. (Shirley, MA) |
| Abstract | A method and an apparatus which delay initiation of a shut down procedure
in a computer to allow the riding through of variations in a power supply.
An interrupter receives and interrupts an asserted shut down signal and
outputs an interrupt signal when the shut down signal has been asserted. A
gate trigger is coupled to the interrupter and triggers an energy booster
to raise the power supplied to the computer when the gate trigger receives
the interrupt signal from the interrupter. The amount of energy remaining
in the energy booster is monitored by a monitor and a depletion signal is
outputted when the amount of energy remaining in the energy booster is
below a reference value. An output stage has inputs coupled to the
interrupter and the monitor, and receives at these inputs the interrupt
signal and the depletion signal and outputs a re-asserted shut down signal
to the computer when both the interrupt signal and the depletion signal
are present at the inputs of the output stage. |
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Title Information  |
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| Publication Date |
April 4, 1989 |
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Title Information |
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| Market Size |
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| Reasonable Royalty |
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Public's "Guesstimation" of Royalty Value
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| Market Size | N/A | [No votes] | | x | Market Share | N/A | [No votes] | | x | Reasonable Royalty | N/A | [No votes] |
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Market Review |
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Technical Review |
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Claims |
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What is claimed is:
1. A device for riding through variations in a power supply and delaying
initiation of a shut down procedure in a computer, the device comprising
an energy booster for raising the power supplied to the computer;
an interrupter for receiving and interrupting an asserted shut down signal
and outputting an interrupt signal when said shut down signal has been
asserted;
a gate trigger coupled to said interrupter and said energy booster for
triggering said energy booster to raise the power supplied to the computer
when said gate trigger receives said interrupt signal from said
interrupter;
means for monitoring an amount of energy remaining in said energy booster
coupled to said energy booster, said means for monitoring outputting a
depletion signal when the amount of energy in said energy booster is below
a reference value; and
an output stage having inputs coupled to said interrupter and said means
for monitoring, said output stage receiving at said inputs said interrupt
signal and said depletion signal and outputting a re-asserted shut down
signal to said computer when both said interrupt signal and said depletion
signal are present at the inputs of said output stage.
2. The device of claim 1, wherein said means for monitoring comprises a
voltage divider having an input coupled to said energy booster, and a
comparator coupled at one input to a reference voltage supply to receive a
reference voltage and at another input to said voltage divider to receive
a remaining energy voltage from said voltage divider.
3. The device of claim 2, wherein said means for monitoring further
comprises an isolator coupled between the comparator and the output stage,
said isolator issuing said depletion signal upon receiving a signal from
said comparator indicating said remaining energy voltage is below said
reference voltage.
4. The device of claim 3, wherein said isolator is an optical isolator.
5. The device of claim 4, wherein said interrupter includes a logic gate
which receives as inputs said shut down signal and a constant signal, and
outputs said interrupt signal when said shut down signal is asserted.
6. The device of claim 5, wherein said logic gate is a NAND gate.
7. The device of claim 3, wherein said gate trigger includes a transistor
controlled by said interrupt signal, a resistor and a capacitor both
connected at one end to said transistor, and an isolating transformer
connected to both said resistor and said capacitor at the other ends of
said resistor and said capacitor, said isolating transformer outputting a
trigger signal to trigger said energy booster when said interrupt signal
is received by said transistor.
8. The device of claim 1, wherein said interrupter includes a logic gate
which receives as inputs said shut down signal and a constant signal, and
outputs said interrupt signal when said shut down signal is asserted.
9. The device of claim 8, wherein said logic gate is a NAND gate.
10. The device of claim 1, wherein said gate trigger includes a transistor
controlled by said interrupt signal, a resistor and a capacitor both
coupled at one end to said transistor, and an isolating transformer
coupled to both said resistor and said capacitor at the other ends of said
resistor and said capacitor, said isolating transformer outputting a
trigger signal to trigger said energy booster when said interrupt signal
is received by said transistor.
11. A method for causing a computer to ride through a variation in power
supplied to the computer, the variation being indicated by an asserted
shut down signal, the method comprising the steps of:
(a) interrupting the asserted shut down signal;
(b) controlling an energy booster upon assertion of the shut down signal to
boost the power supplied to the computer; and
(c) outputting to the computer a re-asserted shut down signal to allow
initiation of a shut down of the computer when an amount of energy in said
energy booster is below a reference value and said shut down signal is
re-asserted.
12. The method of claim 11, wherein step (c) further comprises the step of
comparing in an operational amplifier the amount of energy in said energy
booster with the reference value.
13. The method of claim 12, wherein said comparing step includes the step
of converting the amount of energy in said energy booster and the
reference value into voltages which are inputs to said operational
amplifier
14. The method of claim 13, wherein said comparing step includes
controlling an isolator in accordance with an output of said operational
amplifier.
15. The method of claim 12, wherein step (c) includes controlling an output
stage according to a signal from an output of the isolator and from said
asserted shut down signal, said output stage outputting said re-asserted
shut down signal when the energy of said energy booster is below the
reference value and the shut down signal is asserted.
16. The method of claim 11, wherein step (b) includes the step of operating
a gate trigger in response to assertion of the shut down signal such that
said gate trigger triggers the energy booster to boost the power supplied
to the computer. |
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Claims |
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Description |
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FIELD OF THE INVENTION
The invention is related to the field of supplying power to a computer.
More specifically, the invention is related to a device and a method which
allows a computer to ride through variations in the power supply voltage
without immediately causing initiation of a shut down procedure of the
computer.
BACKGROUND OF THE INVENTION
Computer users normally depend upon a local electric utility company to
provide energy that is within a specified voltage range. When the voltage
deviates from this range, even briefly, many computers follow an orderly
shut down procedure. Shutting down results in lost work time for the
operator.
Devices are known which monitor the power supplied to the computer and
initiate a shut down procedure when the supply voltage reaches a certain
value, the AC low voltage. The monitor outputs an AC low signal to the
computer when the AC low voltage is reached. Once this AC low signal is
asserted by the monitor, the shut down procedure is begun, and the known
devices cause the computer to stop processing and to perform housekeeping
functions which prevent a significant loss of information.
The vast majority of voltage supply problems are of short duration, on the
order of 100-500 msec. By providing a device which allows the computer to
ride through a short duration voltage supply problem, the initiation of
the shut down procedure would be avoided in most instances However, when
the problem persists beyond the short duration, the shut down procedure
should be initiated.
SUMMARY OF THE INVENTION
It is therefore an object of the invention to provide a method and
apparatus which allow a computer to ride through short duration variations
in a power supply voltage.
This and other objects are achieved according to the invention by a device
which delays initiation of a shut down procedure in a computer, the device
comprising an interrupter for receiving and interrupting an asserted shut
down signal. The interrupter outputs an interrupt signal when the shut
down signal has been asserted A gate trigger is coupled to the interrupter
and triggers an energy booster to raise the power supplied to the computer
when the gate trigger receives the interrupt signal from the interrupter.
A means for monitoring the amount of energy remaining in the energy
booster is coupled to the energy booster and outputs a depletion signal
when the amount of energy in the energy booster is below a reference
value. An output stage is coupled to the interrupter and the means for
monitoring and receives as inputs the interrupt signal and the depletion
signal. The output stage outputs a re-asserted shut down signal when both
the interrupt signal and the depletion signal are present at the inputs of
the output stage.
The above and other objects are also achieved according to the invention by
a method for causing a computer to ride through a variation in power
supplied to the computer, where the variation is indicated by an asserted
shut down signal. The method comprises the steps of: interrupting the
asserted shut down signal; controlling an energy booster upon assertion of
the shut down signal to boost the power supplied to the computer; and
outputting to the computer a re-asserted shut down signal to allow
initiation of a shut down of the computer when the energy of the energy
booster is below a reference value and the shut down signal is asserted.
The device and method according to the present invention provide the
advantage of avoiding the shutting down of a computer when the variation
in the power supply voltage is of short duration, while still allowing an
orderly shut down procedure to occur if the variation is of longer
duration.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a block diagram of the power input stages of a computer
according to the prior art.
FIG. 1a is a graph of the voltage across an input capacitor plotted against
the time after the beginning of a variation in the power supply voltage.
FIG. 2 shows a block diagram of the power input stages of a computer
according to the present invention.
FIG. 2a is a graph of the voltage across an input capacitor plotted against
the time after the beginning of a variation in the power supply voltage.
FIG. 3 is a schematic diagram of the ride through circuit shown in block
form in FIG. 2 constructed according to an embodiment of the present
invention.
DETAILED DESCRIPTION
FIG. 1 shows a prior art arrangement of power input stages for a computer.
An AC/DC converter 10 converts the utility voltage to a DC bulk voltage.
This DC bulk voltage is supplied to DC/DC converters, not shown, which
power the computer over lines 16 and 18.
A monitor 12 monitors the DC bulk voltage and outputs two status signals to
the computer shut down logic (not shown) of the computer An AC low signal
is output over line 20 and a DC low signal is output over line 22. The AC
low signal informs the computer shut down logic that there is just enough
energy left to perform the housekeeping functions required to prevent a
significant loss of information. The computer stops operating after the AC
low signal is asserted. The DC low signal, which is always preceded by the
AC low signal during a power down sequence, informs the computer that one
or more DC/DC converters outputs are out of regulation. The computer is
typically down within microseconds after the assertion of the DC low
signal. The time between the assertion of the AC low signal and the DC low
signal is known as the hold up time, shown graphically in FIG. 1a (t.sub.2
-t.sub.1), and can be extended by hold-up time extenders. The time
(t.sub.1 -t.sub.0) is the ride through of a prior art arrangement
operating at a nominally specified utility power source input. At the
minimally specified utility power source input, this prior art arrangement
provides no ride through.
The battery backup 14 of FIG. 1 charges the backup capacitor 15 to provide
enough power for the computer to maintain a specified level of
intelligence during a power failure. However, not every drop in voltage
indicates a power failure, necessitating initiation of a shut down
procedure. By "riding through" these occasional short duration voltage
drops, the use of the computer will not be disturbed. One approach to
avoiding the initiation of a shut down is the use of a motor generator
with a flywheel to maintain the input voltage. This approach is expensive
in terms of real estate and cost.
The present invention avoids shut down by interrupting an asserted AC low
signal and boosting the voltage with the arrangement shown in FIG. 2. The
monitor 12 of the prior art is connected to a ride through logic circuit
24. As will be explained in more detail below, the ride through logic
circuit 24 interrupts an asserted AC low signal and triggers an energy
booster 26. Energy boosters themselves are well known.
The ride through logic circuit 24 causes the voltage V.sub.c to be raised
by the energy booster 26 when the AC low signal is asserted. This is
illustrated in FIG. 2a. A long ride through time is thereby provided, the
ride through time being defined as the time between loss of nominally
specified utility power source input to the computer and the time at which
the voltage V.sub.c has decreased to the AC low signal voltage (t.sub.3
-t.sub.0) At the minimum specified power source input, the present
invention provides a ride through time of (t.sub.3 -t.sub.1).
Hopefully, during this ride through time, the voltage supply has returned
to normal, obviating the need for initiation of a shut down. If at t.sub.3
the voltage supply has not returned to normal and V.sub.c has decreased to
the AC low voltage, then shut down is initiated by the shut down logic,
which receives a re-asserted AC low signal from the ride through logic
circuit 24 on line 28.
An embodiment of the ride through logic circuit 24 according to the
invention is shown in FIG. 3, connected to the energy booster 26. The
major components of the logic circuit 24 are an interrupter 30, a gate
trigger 32, a comparator 34 and an output stage 36.
The interrupter 30 receives as an input the AC low signal from the monitor
12. Although other logic can be used, the embodiment illustrated in FIG. 3
comprises a NAND gate 38, which has as its inputs the AC low signal from
monitor 12 and a high signal from a secondary bias source. The primary
bias source is a voltage source referenced to the utility power source
input, whereas the secondary bias source is a voltage source that is
isolated from the primary bias source in order to maintain a required
safety integrity. The output of gate 38 will always be low until the AC
low signal is asserted (becomes low). The gate 38 will then output a high
signal on line 40 to both the gate trigger 32 and the output stage 36.
The gate trigger 32 receives the high signal on line 40 through resistor
42, which is connected to the gate of transistor 44. The drain of
transistor 44 is connected to a resistor 46 and a capacitor 48 which are
in parallel. The resistor 46 and capacitor 48 are each connected to a
transformer 50, the output of which is connected to the energy booster 26.
The transformer provides the required isolation between the primary and
secondary bias sources to maintain safety integrity for the gate trigger
32 and thus can be considered an isolating transformer. When a high signal
is on line 4 (the AC low signal is asserted), the transistor 44 turns on,
causing the gate trigger 32 to trigger the energy booster 26 so that it
can raise V.sub.c across capacitor 15.
The comparator 34 includes an operational amplifier (op amp) 52 which
receives at its negative input a reference voltage established by a zener
diode 54 and a shunt resistor 56. The op amp 52 is powered by the primary
bias supply voltage on line 58. The value of the amount of energy
remaining in the energy booster 26 is input to the comparator 34 at
resistor 60, which together with resistor 62, forms a voltage divider. The
op amp 52 receives at its positive input the value from the voltage
divider, which is proportional to the value received from the energy
booster 26. The op amp 52 outputs a low signal whenever the signal at its
positive input is less than at its negative input. In other words, the op
amp 52 will output a low signal when the energy remaining in the energy
booster 26 falls below a reference value.
The output of op amp 52 is connected to a resistor 64, which is connected
to the input of optical isolator 68. When the input voltage to the optical
isolator is high, a low will be present at line 70, which is connected
between the collector of optical isolator 68 and the output stage 36. When
the input of optical isolator 68 is low, a high will be present on line
70. Again, the optical isolator 68 provides the required isolation to
maintain safety integrity for the comparator 34. In summary, the output of
op amp 52 goes low when the energy remaining in the energy booster 26
falls below a reference value. This causes the voltage at the input of
optical isolator 68 to go low, which causes a high signal to be present on
line 70.
The output stage 36 is a NAND gate 36 in the illustrated embodiment. The
two inputs for the NAND gate 36 are from the output of NAND gate 38 and
from the comparator 34 (on line 70). A low signal will be output from the
NAND gate 36 only when both inputs are high. The low signal is received by
a shut down circuit.
The operation of the ride through logic circuit 24 when an AC low signal is
asserted is as follows. The interrupter 30 receives the asserted AC low
signal and prevents it from immediately reaching the shut down circuit.
Upon receipt of the asserted AC low signal, the output of gate 38 goes
high, which causes gate trigger 32 to trigger the energy booster 26. The
voltage across the capacitor 15 (V.sub.c) is raised by the energy from the
energy booster 26. The amount of energy remaining in the energy booster 26
is monitored by the comparator 34. While there is sufficient energy in the
energy booster 26, the comparator 34 outputs a low signal to the output
stage 36, which therefore does not send the asserted AC low signal. It is
only when the energy in the energy booster 26 has been depleted below a
reference value that the comparator 34 outputs a high signal to output
stage 36. If both the AC low signal is asserted on line 40 and the energy
from the energy booster 26 falls below the reference value, then the
output stage 36 outputs an asserted AC low signal to the shut down circuit
to cause an orderly shut down of the computer However, if the power supply
voltage has been restored before the energy from the energy booster 26 has
fallen below the reference value, then the comparator 34 does not output a
high signal to the output stage 36 so that the output of gate 36 will
remain high, and the shut down procedure will not be initiated by the
computer. Thus, short duration drops in the power supply to the computer
can be tolerated without immediate initiation of shut down procedures.
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