JP4222545B2 - Power-saving sensor detection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power saving sensor detection apparatus including a monitoring sensor circuit for returning from an off mode or a sleep mode, and more particularly to a power saving sensor detection apparatus that reduces power consumption in an off mode or a sleep mode.
[0002]
[Prior art]
In a conventional multi-function copier having a copy function, a fax function, a printer function, and a scanner function, a standby state in which the operation can be started immediately is constant in order to reduce power consumption during a period when the multi-function copier is not used. When it continues continuously for more than the time, it automatically shifts to a power saving state that reduces or cuts off the power supplied to the fixing heater of the thermal fixing device and some control circuits. That is, the mode is shifted to the sleep mode in which the user's return request operation and a request from another connected device can be received.
In the power saving state of the sleep mode, only the power LED of the operation unit is lit. The user's operation is only accepted to turn on the power switch, open and close the pressure plate or document feeder (hereinafter referred to as DF), or return to the standby state by setting the document on the DF.
Therefore, it is necessary to energize and operate the pressure plate or DF open / close detection sensor installed in the upper surface of the reading unit or the document presence / absence detection sensor installed in the DF. These sensors use general transmission type photosensors and fillers, and supply a power of 5 V ± 0.5 V and consume a current of about 15 mA. Two sensors consume about 150 mW of power. Considering the conversion efficiency from AC input to 5V output in the PSU, the AC input is about 200 mW, which has a large ratio as a power saving state.
The same problem occurs in the off mode, which is a power saving state of a copying machine having only a copying function.
[0003]
16 and 17 show a conventional return request operation detection device. The 5VE power is always supplied to each sensor and the power switch 1, and the power consumption is large.
[0004]
When the operation in the power saving state is performed, the sub control unit monitors the state of the document sensor and the key sensor, and when a predetermined incoming signal is detected, the main control unit is powered on and the incoming signal In some cases, the operability is improved by notifying the main control unit that it has been detected and starting the system (see Patent Document 1).
[0005]
[Patent Document 1]
JP 2000-1205030 A
[0006]
[Problems to be solved by the invention]
As described above, the power consumption in the sleep mode accounts for a large proportion of the energization of the DF open / close detection sensor and the document presence / absence detection sensor installed in the DF. .
Further, there is a possibility that the operator erroneously detects that a return request operation has been performed even though the power saving process is merely performed in the power saving state.
The present invention takes this situation into consideration. Specifically, the object of each claim is as follows.
[0007]
According to the first aspect of the present invention, the power consumption of the sensor is reduced, and even if the output of the sensor changes when the power is reduced, it is intended to prevent the operator from erroneously detecting that a return request operation has been performed. .
[0008]
According to the second aspect of the present invention, the power consumption of the sensor is set to 0 to obtain the greatest power reduction effect.
[0009]
According to the third aspect of the present invention, it is an object of the present invention to prevent the operator from erroneously detecting that a return request operation has been performed even if the output of the sensor changes when the power consumption of the sensor is reduced.
[0010]
In the invention of claim 4, even if the operator performs a return request operation while reducing the power consumption of the sensor, the return request operation is performed when the power consumption of the sensor is returned to the normal state. The purpose is to detect.
[0011]
According to the fifth aspect of the present invention, even if the output of the sensor changes when the power consumption of the sensor is reduced, it is intended to prevent erroneous detection that the operator has made a return request operation.
[0012]
It is an object of the present invention to improve the responsiveness of the return request operation and reliably detect the request.
[0013]
The invention of claim 7 aims to reduce the power consumption of the sensor and prevent erroneous detection that the operator has made a return request operation even if the output of the sensor changes at the time of power reduction. .
[0014]
It is an object of the present invention to enable detection of the output state of a sensor at any time.
[0015]
It is an object of the present invention to always grasp the output state of a sensor by monitoring an appropriate signal depending on whether the power consumption of the sensor is reduced or not.
[0016]
In the invention of claim 10, by intermittently operating the sensor and the edge detection circuit, the sensor stop time is lengthened in the power saving state of the sleep mode or the off mode, and the sensor stop time is shortened in the standby state or the operation state. An object is to reduce the power consumption of the sensor in a power saving state where low power is important and to detect a change in a short time in a standby state or an operating state where detection time is important.
[0017]
[Means for Solving the Problems]
In order to solve such an object, the invention described in claim 1 is directed to a sensor that detects the state of the device, a detection unit that detects a change in the output of the sensor, and that the detection unit detects a change in the output of the sensor. In a power saving sensor detection apparatus having a storage means for storing, a reduction means for temporarily reducing power consumption of the sensor, a stop means for temporarily stopping the operation of the detection means for detecting a change in sensor output, and a sensor And a synchronization unit that synchronizes a reduction unit that temporarily reduces power consumption and a stop unit that temporarily stops the operation of the detection unit that detects a change in the output of the sensor.
[0018]
The invention described in claim 2 is characterized in that, in the invention described in claim 1, as a reduction means for temporarily reducing the power consumption of the sensor, there is a cutoff means for cutting off the power supply to the sensor.
[0019]
According to a third aspect of the present invention, in the first aspect of the invention, the holding means for sample-holding the sensor output is provided as a stop means for temporarily stopping the operation of the detection means for detecting a change in the sensor output. It is characterized by that.
[0020]
According to a fourth aspect of the present invention, in the first aspect of the present invention, when the operation of the detecting means for detecting a change in the output of the sensor returns from the temporarily stopped state to the operating state, the stopped state is set. Comparing means for comparing the output of the sensor before entering with the output of the sensor when returning and detecting a change in the output of the sensor is provided.
[0021]
According to a fifth aspect of the invention, in the first aspect of the invention, the stop means for temporarily stopping the operation of the detection means for detecting a change in the output of the sensor is a reduction for temporarily reducing the power consumption of the sensor. The detection means for detecting a change in the output of the sensor is performed before the means, and the operation is temporarily stopped to return to the operation state, and the sensor power consumption is temporarily reduced to the normal state. It is characterized by being delayed for a certain time.
[0022]
According to a sixth aspect of the present invention, in the first aspect of the invention, the reduction means for temporarily reducing the power consumption of the sensor is periodically performed, the period is set to 500 milliseconds or less, and the non-reduction time is set to 1 millimeter. It is characterized by being at least 2 seconds.
[0023]
The invention according to claim 7 has a sensor for detecting the state of the device, a detecting means for detecting a change in the output of the sensor, and a storage means for storing that the detecting means has detected a change in the output of the sensor. In a power-saving sensor detection device having a reduction means for temporarily reducing the power consumption of the sensor and a stop means for temporarily stopping the operation of the detection means for detecting a change in the output of the sensor, The detection means for detecting a change in the output of the sensor is performed only immediately before the temporary reduction is started.
[0024]
The invention described in claim 8 is characterized in that in the invention described in claim 7, it has a digital input port for connecting a signal from a sensor for detecting the state of the device.
[0025]
According to a ninth aspect of the present invention, in the invention according to the eighth aspect, during the period when the power consumption of the sensor is temporarily reduced, the output of the detection means for detecting a change in the output of the sensor is monitored, and the sensor It is characterized in that the output of the digital input port is monitored during a period in which the power consumption is not reduced.
[0026]
The invention according to claim 10 has a sensor for detecting the state of the device, a detecting means for detecting a change in the output of the sensor, and a storage means for storing that the detecting means has detected a change in the output of the sensor. In the power-saving sensor detection device having a reduction means for temporarily reducing the power consumption of the sensor and a stop means for temporarily stopping the operation of the detection means for detecting a change in the output of the sensor, The temporary reduction of the power consumption and the temporary stop of the operation of the detection means for detecting the change of the sensor output by the stop means are periodically performed in synchronization, and the ratio of the stop time to the cycle time is plural. It has the ratio setting means to set, It is characterized by the above-mentioned.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0028]
The multi-function copier shown in FIG. 1 has a copy function, a document box function, a fax function, a printer function, and a scanner function. Further, in the sleep mode in the power saving state, the energization to the fixing heater is stopped, and the energization to the white unit in FIG. 1 is stopped to reduce the power consumption. This energization control is performed by controlling the PSU 5 by a PSU activation signal from the controller 4.
[0029]
The means for the user to return from the sleep mode in the power saving state to the standby state includes three means 4 operations of turning on the power switch 1, opening and closing the pressure plate or DF, and setting the original on the DF, and signals for detecting the operations. Is sent to the controller 4, and the controller 4 operates the PSU activation signal to start energization to the unit that has been de-energized during the sleep mode.
[0030]
Either the pressure plate or the DF is attached to the document reading apparatus. The pressure plate / DF opening / closing detection sensor 2 can detect opening / closing regardless of which is attached. Further, when the pressure plate is attached instead of the DF, there is no DF, and the user's return means is the two means 3 operation of turning on the power switch 1 and opening and closing the pressure plate.
[0031]
Also, the return operation from the sleep mode is performed by a reception signal from the fax control board and a reception signal from the PHY board or 1394 board connected to the host computer.
[0032]
The PSU 5 shown in FIG. 2 has two converters, a main converter and a sub-converter. In the sleep mode, the sub-converter is stopped by the PSU activation signal, and the switch included in the 5V output of the main converter is turned off. Accordingly, power is supplied only to the 5VE power supply. The other 5V, 12V, -12V, and 24V power supplies stop supplying power.
[0033]
<First Embodiment>
The return request operation detection device as the first embodiment of the present invention shown in FIG. 3 includes a sensor signal detector 6, a switch 7, a switch delay device 8, a continuous detection / intermittent detection switching device 9 and a timer on the controller 4. 10, a level stabilizing resistor 11, a pressure plate / DF opening / closing detection sensor 2, a document presence / absence detection sensor 3, and a power switch 1.
[0034]
The sensor signal detector 6 always monitors the signals from the sensors and the power switch 1 while the XENABLE signal is at the L level. When the signal level changes, the interrupt controller 12 responds to the changed state. Generated signal. The CPU 13 sets a return factor to be accepted by the interrupt controller 12 in advance. In the case of an apparatus to which a DF is attached, there are four types of pressure plate closing, pressure plate opening, document setting, and power source SWON. The interrupt controller 12 generates an interrupt request signal: INT to the CPU 13 when receiving the return factor signal to be received.
[0035]
The energization control to each sensor and the power switch 1 and the edge detection operation control of the sensor signal detector 6 are controlled by an intermittent signal generated by the timer 10 and a continuous signal generated by the CPU 13. The timer 10 generates a clock with a fixed period.
[0036]
When the continuous signal is at the H level, the XENABLE signal is always at the L level, and the switch 7 is turned on to energize each sensor and the power switch 1. The edge detection operation of the sensor signal detector 6 is always performed. When the continuous signal is at the L level, the XENABLE signal periodically becomes H level due to the intermittent signal, the switch 7 is turned OFF, the power supply to each sensor and the power switch 1 is cut off, and the sensor signal detector 6 The edge detection operation is stopped.
[0037]
FIG. 4 shows details of the sensor signal detector 6. The signal from each sensor and the power switch 1 detects the state after the change of the signal level by the respective sample-and-hold device, edge detector and memory. While the edge detection operation is stopped by operating the sample hold device with the XENABLE signal, the state before the stop is held. The edge detector looks at the output of the sample and hold device, detects a rising edge and a falling edge, and sets a memory for each rising and falling edge. The output of each memory is output as the output of the sensor output device. Further, each memory is reset when a memory clear signal is received.
[0038]
An internal clock from an oscillator (not shown) is supplied to the D-FF and shift register in the sensor signal detector 6. Although a time delay of one internal clock period occurs every time one stage passes through the D-FF, since it is sufficiently shorter than the period of the intermittent signal, the sensor signal detector 6 other than the delay 2 generated in the shift register The following timing will be described assuming that the delay is zero.
[0039]
FIG. 5 shows the timing of the intermittent signal, continuous signal, power shutoff, and edge detection operation. As described above, while the continuous signal is at the H level, the XENABLE signal that is the output of the continuous detection / intermittent detection switch 9 is at the L level, and the power of each sensor and the pull of the signal of each sensor and the power switch 1 A 5VE power supply is supplied to the 5VS power supply of the up resistor through the switch 7. Since a voltage drop of about 0.3 V occurs in the switch 7, the voltage of the 5VS power supply is about 4.7V. Since power is supplied, the detection operation of each sensor and the power switch 1 is in an operating state. Further, the edge detection operation of the sensor signal detector 6 is also in an operating state, and a change in state can be detected at any time.
[0040]
When the continuous signal becomes L level, the level of XENABLE changes due to the intermittent signal. If the intermittent signal is at the L level when the continuous signal is at the L level, the XENABLE signal is at the H level as indicated by (1) in FIG. At the same time, the edge detection operation of the sensor signal detector 6 is stopped. After the time of the delay 1 generated by the switch delay device 8, the switch 7 is turned OFF, 5VS is cut off from 5VE, and becomes 0V by the level stabilizing resistor 11. The level stabilization resistor 11 is provided between 5VS and GND in order to prevent an unstable state where the input of the sensor signal detector 6 is neither H level nor L level without the voltage of 5VS dropping to 0V completely. Insert into.
[0041]
At the same time, the detection operation of each sensor and the power switch 1 is stopped. Therefore, before the detection operation of each sensor and the power switch 1 is stopped, the edge detection operation of the sensor signal detector 6 is stopped, and before the detection operation of each sensor and the power switch 1 is reliably stopped. Can be maintained.
[0042]
Next, as shown in (2), when the intermittent signal becomes H level, the XENABLE signal becomes L level, and after the time of delay 1 generated by the switch delay device 8, the switch 7 is turned on and the 5VS power supply is energized. The detection operation of the sensor and the power switch 1 returns to the operating state. The edge detection operation of the sensor signal detector returns to the operating state after a time of delay 2 generated by the sample delay device of FIG. 4 after the intermittent signal becomes H level. Since the time of delay 2 is longer than the time of delay 1, when the edge detection operation of the sensor signal detector returns to the operation state, the detection operation of each sensor and the power switch is already in a stable operation state.
[0043]
Next, as shown in (3), when the intermittent signal becomes L level, the XENABLE signal becomes H level and the same operation as in (1) is repeated. Therefore, when the continuous signal is at the L level, the duty at which the 5VS power is supplied depends on the L level duty of the intermittent signal.
Power supply duty = T2 / (T1 + T2) T1 and T2 are shown in FIG.
[0044]
FIG. 6 shows the operation of the sensor signal detector 6 of FIG. 4 taking as an example the case where the pressure plate or DF is opened and closed. The pressure plate opening / closing signal, which is the output of the pressure plate / DF opening / closing detection sensor 2, becomes H level when the pressure plate or DF is closed, and becomes L level when the pressure plate or DF is open.
[0045]
As shown in (1) of FIG. 6, when the pressure plate or DF is opened and the pressure plate opening / closing signal changes from H level to L level, the XENABLE signal is L level and the output OUT signal of the sample delay becomes L. If this is the case, it is the edge detection operation operating period, and the output OUT signal of the sample and hold device 1 immediately changes from H level to L level. The falling edge is detected by the edge detector 1 and an OUT_F signal is generated to set the pressure plate open signal of the memory 1 to the H level.
[0046]
As shown in (2) of FIG. 6, even if the pressure plate or DF is closed, while the XENABLE signal is at the H level, the detection operation of the sensor is stopped. do not do. After the XENABLE signal becomes L level and the delay 1 time, the sensor detection operation is activated and the pressure plate opening / closing signal changes from L level to H level, but is still in the edge detection operation stop period, and the output OUT signal of the sample delay is Since it is still at the H level, the output of the sample hold device does not change. If the output OUT signal of the sample delay device becomes L level after the time of delay 2 and the edge detection operation is in operation period, the pressure plate open / close signal is still at H level, as shown in (3), the sample hold device 1 Output from the L level to the H level. The edge detector 1 detects this rising edge, generates an OUT_R signal, and sets the pressure plate closing signal of the memory 1 to the H level.
[0047]
When the XENABLE signal becomes H level when the pressure plate or DF is closed as indicated by (4) in FIG. Changes from H level to L level. However, at this time, since the output OUT signal of the sample delay device is at the H level and the edge detection operation is stopped, the output of the sample hold device remains at the H level and does not change.
[0048]
When the memory clear signal is received as shown in (5) of FIG. 6, the memory is reset, and both the pressure plate open signal and the pressure plate close signal become L level.
[0049]
FIG. 7 shows control of the entire copying machine using the return request operation detection device of the first embodiment, taking as an example the case where a document is set on the DF.
[0050]
CPU13 will stop supply of power supplies other than 5VE power supply using a PSU starting signal, if the conditions for transfer to sleep states, such as the time passage in the preset standby state, are satisfied. Next, the continuous signal to the continuous detection / intermittent detection switching device 9 is set to the L level to set the intermittent detection state. Next, it shifts itself to a standby state to reduce power consumption and to enter a sleep state.
[0051]
As shown in (1) of FIG. 7, when the first edge detection operation operation period comes after the user sets the document on the DF, a document set signal is generated from the sensor signal detector 6 to the interrupt controller 12. Since the CPU 13 has previously set the document set as an interrupt generation condition in the interrupt controller 12, an INT signal is generated to the CPU 13. Then, the operation state of the CPU 13 returns to the normal state, and the factor register of the interrupt controller 12 is read to detect from which means the return request from the sleep mode is generated.
[0052]
The interrupt controller 12 having read the cause register generates a memory clear signal to the sensor signal detector 6. As a result, the document set signal of the sensor signal detector 6 is cleared.
[0053]
As shown in (2) in FIG. 7, the CPU 13 that has found that the return request has been generated by the document set to the DF shifts the copier state from the sleep mode to the standby mode according to a predetermined procedure.
[0054]
As described above, in order to reduce the average power consumption of the pressure plate / DF opening / closing detection sensor 2 and the document presence / absence detection sensor 3 in the sleep mode, the duty of the energization time may be reduced. That is, the period may be lengthened and the energization time may be shortened. However, if the cycle is lengthened, the time from when the user operates the return request until the CPU 13 actually detects the return request may be longer. If the cycle is longer than 500 milliseconds, the operability deteriorates. It becomes prominent. In particular, the power switch 1 is turned off when the operator depresses it even if it is turned on. Therefore, if the pressing time is shorter than the cycle, it cannot be detected at all and the operability is particularly good. Deteriorate.
[0055]
Also, if the energization time is shortened, it becomes impossible to secure the time from the start of energization until the operation of the sensor becomes stable. Therefore, if the energization time is shortened from 1 millisecond, a stable operation cannot be obtained.
[0056]
When the energization time is set to 2 milliseconds with a period of 200 milliseconds, the average power consumption of the sensor becomes 1/100, and good operability and stable operation can be obtained.
[0057]
<Second Embodiment>
The return request operation detecting device as the second embodiment of the present invention shown in FIG. 8 includes a sensor signal detector 6, a switch 7, a switch delay device 8, a continuous detection / intermittent detection switching device 9 and a timer on the controller 4. 10, a level stabilization resistor 11, a PIO 14, a pressure plate / DF opening / closing detection sensor 2, a document presence / absence detection sensor 3, and a power switch 1. The difference from FIG. 3 is that a PIO 14 connected to the CPU 13 is added, and signals from each sensor and the power switch 1 are also connected to the PIO 14.
[0058]
FIG. 9 shows details of the sensor signal detector 6. The difference from FIG. 4 is that the signals from the sensors and the power switch 1 are first received by a latch instead of the sample-and-hold device, and the sample delay device of the XENABLE signal is deleted.
[0059]
Signals from the sensors and the power switch 1 detect the state after the signal level changes by the respective latches, edge detectors and memories. While the edge detection operation is stopped by operating the latch by the XENABLE signal, the state before the stop is held. The edge detector looks at the output of the latch, detects a rising edge and a falling edge, and sets a memory for each rising and falling edge. The output of each memory is output as the output of the sensor output device. Further, each memory is reset when a memory clear signal is received.
[0060]
An internal clock from an oscillator (not shown) is supplied to the D-FF in the sensor signal detector 6. Although a time delay of one internal clock period occurs every time one stage passes through the D-FF, the delay in the sensor signal detector 6 is assumed to be 0 because it is sufficiently shorter than the period of the intermittent signal. I do.
[0061]
FIG. 10 shows the timing of the intermittent signal, continuous signal, power shut-off, and edge detection operation. The difference from FIG. 5 is that the sensor signal detector edge detection operation is activated only when the XENABLE signal rises.
As described above, while the continuous signal is at the H level, the XENABLE signal that is the output of the continuous detection / intermittent detection switch 9 is at the L level, and the power of each sensor and the pull of the signal of each sensor and the power switch 1 A 5VE power supply is supplied to the 5VS power supply of the up resistor through the switch 7. Since a voltage drop of about 0.3 V occurs in the switch 7, the voltage of the 5VS power supply is about 4.7V. Since power is supplied, the detection operation of each sensor and the power switch 1 is in an operating state. However, the edge detection operation of the sensor signal detector 6 remains stopped.
[0062]
When the continuous signal becomes L level, the level of the XENABLE signal changes due to the intermittent signal. If the intermittent signal is at the L level when the continuous signal is at the L level, the XENABLE signal is at the H level as indicated by (1) in FIG. Then, at that moment, the edge detection operation of the sensor signal detector is activated, and the signals of the sensors and the power switch 1 are captured. After the time of the delay 1 generated by the switch delay device 8, the switch 7 is turned OFF, 5VS is cut off from 5VE, and becomes 0V by the level stabilizing resistor 11. The level stabilization resistor 11 is provided between 5VS and GND in order to prevent an unstable state where the input of the sensor signal detector 6 is neither H level nor L level without the voltage of 5VS dropping to 0V completely. Insert into.
[0063]
At the same time, the detection operation of each sensor and the power switch 1 is stopped. Therefore, it is possible to reliably maintain the state before the detection operation of each sensor and the power switch 1 is stopped.
[0064]
Next, as shown in (2), when the intermittent signal becomes H level, the XENABLE signal becomes L level, and after the time of delay 1 generated by the switch delay device 8, the switch 7 is turned on and the 5VS power supply is energized. The detection operation of the sensor and the power switch returns to the operating state.
[0065]
Next, as shown in (3), when the XENABLE signal becomes H level and the edge detection operation of the sensor signal detector 6 is in an operating state, the detection operation of each sensor and the power switch 1 is already in a stable operating state. ing.
[0066]
FIG. 11 shows the operation of the sensor signal detector 6 of FIG. 9 taking as an example the case where the pressure plate or DF is opened and closed. The pressure plate opening / closing signal, which is the output of the pressure plate / DF opening / closing detection sensor 2, becomes H level when the pressure plate or DF is closed, and becomes L level when the pressure plate or DF is open.
[0067]
As shown in (1) of FIG. 11, after the pressure plate or DF is opened and the pressure plate opening / closing signal changes from H level to L level, the XENABLE signal first changes to H level shown in (2) of FIG. At this time, the output OUT signal of the latch 1 changes from the H level to the L level. The falling edge is detected by the edge detector 1 and an OUT_F signal is generated to set the pressure plate open signal of the memory 1 to the H level.
[0068]
As indicated by (3) in FIG. 11, even if the platen or DF is closed, the period during which the XENABLE signal is at the H level is the sensor detection operation stop period. Since the 5VS power supply is 0V, the pressure plate open / close signal remains at the L level and does not change. The XENABLE signal becomes L level and the sensor detection operation is activated after a delay of 1 and the pressure plate opening / closing signal changes from L level to H level, but is still in the edge detection operation stop period, and the output of the edge detector does not change. . When the XENABLE signal shown in (4) of FIG. 11 changes to H level and the edge detection operation operation period is reached, the output of the latch 1 changes from L level to H level if the pressure plate open / close signal is still at H level. . The edge detector 1 detects this rising edge, generates an OUT_R signal, and sets the pressure plate closing signal of the memory 1 to the H level.
[0069]
As shown in (5) of FIG. 11, when the memory clear signal is received, the memory is reset and both the pressure plate open signal and the pressure plate close signal become L level.
[0070]
FIG. 12 shows control of the entire copying machine using the return request operation detection device of the second embodiment, taking as an example the case where a document is set on the DF. The difference from FIG. 7 is that the sensor signal detector document set is at the H level when the XENABLE signal first changes to the H level after the document presence / absence state is entered.
[0071]
In the second embodiment, unlike the description in FIG. 7, the sensor signal detector 6 can detect that the state of each sensor and the power switch 1 has changed, only in the intermittent detection state that reduces the power consumption of the sensor. Become. In the continuous detection state, since the XENABLE signal remains at the L level, the operation of the sensor signal detector 6 is stopped.
[0072]
Therefore, the signals of the sensors and the power switch 1 are connected to the PIO 14 shown in FIG. 8, and the CPU 13 monitors the states of the sensors and the power switch 1 through the PIO 14 in the continuous detection state.
[0073]
However, when the CPU 13 needs to detect only when the copying machine is in the sleep mode in which it is desired to reduce the power consumption of the sensor, it is not necessary to provide the PIO 14 shown in FIG.
[0074]
<Third Embodiment>
13 includes a sensor signal detector 6, a switch 7, a switch delay unit 8, a PWM timer 15, a level stabilization resistor 11, and a pressure plate / DF on the controller 4. It consists of an open / close detection sensor 2, a document presence / absence detection sensor 3, and a power switch 1. The difference from FIG. 8 is that the PIO connected to the CPU 13 and the continuous detection / intermittent detection switch 9 are deleted, and the timer 10 is replaced with the PWM timer 15.
[0075]
The PWM timer 15 has an H level output time (OFF time) setting register and an L level output time (ON time) setting register, and a setting value is written from the CPU 13 through the data bus. The PWM timer 15 outputs a pulse having an H level and an L level for a time corresponding to the value set in the setting register based on an internal clock cycle (not shown).
[0076]
The details of the configuration of the sensor signal detector 6 are the same as those in FIG. 9 in the second embodiment, and a description thereof will be omitted.
[0077]
FIG. 14 shows the timing of the XENABLE signal, which is the output of the PWM timer 15, the power shutoff, and the edge detection operation. The difference from FIG. 10 is that the XENABLE signal always repeats H and L because there is no continuous signal.
[0078]
As shown in (1), when the XENABLE signal rises, the sensor signal detector 6 starts an edge detection operation. Thereafter, the 5VS power supply becomes 0V after 1 hour of delay, and the detection operation of the sensor and the power switch 1 stops.
[0079]
Next, after 1 hour from the fall of the XENBLE signal, the 5VS power supply becomes 4.7 V, the detection operation of the sensor and the power switch 1 becomes active, and prepares for the next fall of the XENABLE signal.
[0080]
Since the details of the operation of the sensor signal detector 6 are the same as those of FIG. 11 in the second embodiment taking the case where the pressure plate or DF is opened and closed as an example, the description thereof is omitted.
[0081]
FIG. 15 shows the control of the entire copying machine using the return request operation detection device according to the third embodiment, taking as an example the case where a document is set on the DF. The difference from FIG. 12 is that the CPU 13 shown in (2) writes the PSU activation signal at the same time as the CPU 13 returns to the standby state, and simultaneously writes the OFF time of the PWM timer 15 in a short time for the standby state.
[0082]
The third embodiment differs from the second embodiment in that the XENABLE signal always repeats H and L, so that the state of each sensor and the power switch 1 has changed not only in the sleep mode but also in the standby mode. The sensor signal detector 6 can detect. Therefore, the signals of the sensors and the power switch 1 are connected to the PIO 14 shown in the second embodiment, and the CPU 13 does not need to monitor the states of the sensors and the power switch 1 through the PIO 14 in the continuous detection state.
[0083]
【The invention's effect】
As is clear from the above description, the present invention provides the following effects.
[0084]
According to the first aspect of the present invention, the sensor output change detection is stopped in synchronization with the control for reducing the sensor power consumption, so that the sensor power consumption is reduced and the sensor output is reduced when the power is reduced. Even if it changes, it is possible to prevent the operator from erroneously detecting that the return request operation has been performed.
[0085]
According to the invention of claim 2, since the power supply of the sensor is cut off in order to reduce the power consumption of the sensor, the power consumption of the sensor becomes 0, and the greatest power reduction effect can be obtained.
[0086]
According to the invention of claim 3, since the sensor output state immediately before stopping the sensor output change detection is held and the output change detection is stopped, the sensor output change is not observed. Even if the output of the sensor changes when the power is reduced, it is possible to prevent the operator from erroneously detecting that a return request operation has been performed.
[0087]
According to the invention of claim 4, the sensor output state immediately before stopping the sensor output change detection is held and compared with the state when the sensor output change detection is restarted. Even if the operator performs a return request operation during the reduction, it can be detected that the return request operation has been performed when the power consumption of the sensor is returned to the normal state.
[0088]
According to the fifth aspect of the present invention, the sensor output change detection is stopped before the control for reducing the power consumption of the sensor and the control for returning the power consumption of the sensor to the normal state is performed. Sensor output detection resumes after the operation stabilizes, so even if the sensor output changes when the sensor power consumption is reduced, it is possible to prevent the operator from erroneously detecting that a return request operation has been performed. .
[0089]
According to the invention of claim 6, since the waiting time of the operator is shortened and the operation stabilization time of the sensor is ensured, the operator can improve the responsiveness of the return request operation and detect the request reliably. it can.
[0090]
According to the seventh aspect of the present invention, since the detecting means for detecting the change in the sensor output is performed only immediately before the temporary reduction of the sensor power consumption is started, the power consumption of the sensor is reduced and the power consumption is reduced. Even if the output of the sensor sometimes changes, it can be prevented that the operator erroneously detects that a return request operation has been performed.
[0091]
According to the eighth aspect of the present invention, since the digital input port for connecting the signal from the sensor is provided, the CPU can monitor the state of the sensor even when the sensor signal detector is stopped.
[0092]
According to the ninth aspect of the present invention, since the output of the sensor signal detector is monitored in the sleep mode and the digital input port is monitored in the standby state, the sensor state can always be monitored.
[0093]
According to the invention of claim 10, the sensor and the edge detection circuit are intermittently operated, and the sensor stop time is lengthened in the power saving state of the sleep mode and the off mode, and the sensor stop time is shortened in the standby state and the operation state. Thus, the power consumption of the sensor is further reduced in a power saving state where low power is important, and a change can be detected in a short time in a standby state or an operating state where detection time is important.
[Brief description of the drawings]
FIG. 1 is a control block diagram of a multifunction copying machine to which the present invention is applied.
FIG. 2 is a block diagram of a PSU 5 of a multifunction copying machine to which the present invention is applied.
FIG. 3 is a return request operation detection device in the first embodiment.
4 is a detail of the sensor signal detector 6 of FIG.
FIG. 5 is a transition timing of the detection operation state of each sensor and the power switch 1 and the edge detection operation state of the sensor signal detector 6 of the return request operation detection device in the first embodiment.
6 is an operation example of the sensor signal detector 6 in FIG. 4 when the pressure plate or DF is opened and closed.
FIG. 7 is an operation example of the return request operation detection device when a document is set in the first embodiment.
FIG. 8 is a return request operation detecting device according to the second embodiment.
FIG. 9 is a detail of the sensor signal detector 6 of FIG.
FIG. 10 shows the transition timing of the detection operation state of each sensor and the power switch 1 and the edge detection operation state of the sensor signal detector 6 of the return request operation detection device in the second embodiment.
11 is an operation example of the sensor signal detector 6 of FIG. 9 when the platen or DF is opened and closed.
FIG. 12 is an operation example of the return request operation detection device when a document is set in the second embodiment.
FIG. 13 is a return request operation detection device according to a third embodiment.
FIG. 14 is a transition timing of the detection operation state of each sensor and the power switch 1 and the edge detection operation state of the sensor signal detector 6 of the return request operation detection device in the third embodiment.
FIG. 15 is an operation example of the return request operation detection device when a document is set in the third embodiment.
FIG. 16 shows a conventional return request operation detection device.
17 is a detail of the sensor signal detector 6 of FIG.
[Explanation of symbols]
1 Power switch
2 Pressure plate / DF open / close detection sensor
3 Document presence / absence detection sensor
4 Controller
5 PSU
6 Sensor signal detector
7 switch
8 switch delay
9 Continuous / intermittent detection switch
10 Timer
11 level stabilization resistor
12 Interrupt controller
13 CPU
14 PIO
15 PWM timer

Claims (10)

In a power-saving sensor detection device having a sensor that detects a state of an apparatus, a detection unit that detects a change in the output of the sensor, and a storage unit that stores that the detection unit has detected a change in the output of the sensor.
Reduction means for temporarily reducing power consumption of the sensor, stop means for temporarily stopping the operation of the detection means for detecting a change in sensor output, and reduction means for temporarily reducing power consumption of the sensor And a synchronizing means for synchronizing the stopping means for temporarily stopping the operation of the detecting means for detecting a change in the output of the sensor. The power-saving sensor detection device according to claim 1, further comprising: a cutoff unit that cuts off power supply to the sensor as the reduction unit that temporarily reduces power consumption of the sensor. The power-saving sensor detection device according to claim 1, further comprising a holding unit that samples and holds the sensor output as the stop unit that temporarily stops the operation of the detection unit that detects a change in the output of the sensor. . When the operation of the detecting means for detecting a change in the sensor output is temporarily stopped and returned to the operating state, the output of the sensor before entering the stopped state is compared with the sensor output when returning. The power-saving sensor detection apparatus according to claim 1, further comprising a comparison unit that detects a change in the output of the sensor. The stopping means for temporarily stopping the operation of the detecting means for detecting a change in the output of the sensor is performed before the reducing means for temporarily reducing the power consumption of the sensor, and the change in the output of the sensor is detected. The return from the state in which the operation of the detection means is temporarily stopped to the operation state is delayed for a certain time from the state in which the power consumption of the sensor is temporarily reduced to the return to the normal state. The power saving sensor detection device described. 2. The power saving according to claim 1, wherein the reduction means for temporarily reducing the power consumption of the sensor is periodically performed, the period is set to 500 milliseconds or less, and the non-reduction time is set to 1 millisecond or more. Sensor detection device. A sensor for detecting a state of the device, a detection unit for detecting a change in the output of the sensor, and a storage unit for storing that the detection unit has detected a change in the output of the sensor;
In a power-saving sensor detection apparatus comprising: a reduction unit that temporarily reduces power consumption of the sensor; and a stop unit that temporarily stops the operation of the detection unit that detects a change in sensor output.
A power-saving sensor detection apparatus that performs the operation of the detection unit that detects a change in the output of the sensor only immediately before starting to temporarily reduce the power consumption of the sensor. The power-saving sensor detection device according to claim 7, further comprising a digital input port for connecting a signal from a sensor that detects a state of the device. When the sensor power consumption is temporarily reduced, the output of the detection means for detecting a change in the sensor output is monitored, and when the sensor power consumption is not reduced, the output of the digital input port is monitored. The power-saving sensor detection device according to claim 8. A sensor for detecting a state of the device, a detection unit for detecting a change in the output of the sensor, and a storage unit for storing that the detection unit has detected a change in the output of the sensor;
In a power-saving sensor detection apparatus comprising: a reduction unit that temporarily reduces power consumption of the sensor; and a stop unit that temporarily stops the operation of the detection unit that detects a change in sensor output.
The temporary reduction of the power consumption of the sensor by the reduction means and the temporary stop of the operation of the detection means for detecting a change in the output of the sensor by the stop means are periodically performed synchronously, and the cycle time A power-saving sensor detection apparatus comprising ratio setting means for setting a plurality of ratios of stop time with respect to the above.

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