JP5560534B2 - Electronic device, electronic device control program, and threshold setting method - Google Patents

Description

  The present invention relates to an electronic device that operates using a battery as a power source, a control program for the electronic device, and a threshold setting method.

  2. Description of the Related Art Conventionally, an electronic device that operates using a rechargeable battery as a power source is known to have a function of issuing a warning when the remaining battery level becomes a predetermined value or less. While this electronic device stores a predetermined threshold voltage, it detects the output voltage of the battery, and when this output voltage falls below the threshold, it warns by lighting the LED.

The threshold voltage is a value corresponding to a remaining battery level in which the electronic device can be used continuously for a predetermined time (for example, the remaining 10 minutes). Therefore, when the LED is turned on, the user can recognize that the electronic device can be continuously used only for a predetermined time thereafter. (For example, refer to Patent Document 1).
Japanese Patent Laid-Open No. 11-111347

  However, in the case of a battery, the capacity that can be charged decreases due to the deterioration over time with the passage of its use period. And if the chargeable capacity | capacitance falls, even if it is the same voltage, the time which can be used after that will become short. Therefore, if the warning is given when the output voltage of the battery becomes equal to or lower than the predetermined threshold as described above, the time that can be continuously used after the warning is shortened with the deterioration of the battery. For this reason, the remaining usable time intended by the user does not match the actual remaining usable time, and the battery may be unexpectedly exhausted.

  The present invention has been made in view of such a conventional problem, and provides an electronic device, an electronic device control program, and a threshold setting method capable of performing a battery remaining amount warning while suppressing an error in remaining usable time. The purpose is to do.

In order to solve the above-described problem, the electronic device according to the first aspect of the present invention is an electronic device that operates using a battery as a power source, and sets a threshold value as a voltage value of the battery that drives a predetermined operation unit. A determination unit that determines whether or not the predetermined operation unit has been driven , a storage unit that stores data, a detection unit that detects a remaining voltage value of the battery, a comparison unit that compares the remaining voltage value of the battery and the threshold value Means for determining the deterioration state of the battery based on the comparison result by the comparison means and the determination result by the determination means, and the storage means stores the deterioration state of the battery determined by the determination means. And a threshold value control means for variably setting the threshold value.

  According to the present invention, it is possible to issue a battery remaining amount warning while suppressing an error in the remaining usable time.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing an electrical configuration of a projector 1 common to the embodiments of the present invention. The projector 1 operates using a rechargeable battery 29 as a power source, and includes a voltage detection circuit 28, a control unit 11, an input / output interface 12, an image conversion unit 13, a display encoder 14, a display drive unit 15, and the like. . The battery 29 supplies power to each part, and the voltage detection circuit 28 detects the voltage of the battery 29.

  The image signals (image data) of various standards input from the input / output connector unit 16 are unified into image signals of a predetermined format suitable for display by the image conversion unit 13 via the input / output interface 12 and the system bus 17. Then, it is sent to the display encoder 14. The display encoder 14 develops and stores the transmitted image signal in the video RAM 18, generates a video signal from the stored contents of the video RAM 18, and outputs the video signal to the display driving unit 15.

  The display driving unit 15 to which the video signal is input from the display encoder 14 drives the display element 19 which is a spatial light modulation element (SOM) at an appropriate frame rate in accordance with the transmitted image signal. Then, the light bundle emitted from the light source device 20 having a lamp is incident on the display element 19 through the light source side optical system, thereby forming an optical image with the reflected light of the display element 19, and the projection side optical system. An image is projected and displayed on a screen (not shown) through the movable lens group 21. The movable lens group 21 of the projection side optical system is driven by a lens motor 22 for zoom adjustment and focus adjustment.

  The image compression / decompression unit 23 performs recording processing for compressing the luminance signal and the color difference signal in the image signal by processing such as ADTC and Huffman coding, and writing the data onto a memory card 24 that is a detachable recording medium. The image data recorded in the memory card 24 is read out, the individual image data constituting a series of moving images is expanded in units of one frame, sent to the display encoder 14 via the image conversion unit 13, and stored in the memory card 24. Based on the above, it is possible to display a moving image or the like.

  The control unit 11 controls the operation of each circuit in the projector 1, and includes a CPU and its peripheral circuits, a ROM 111, a RAM 112, and the like. The ROM 111 stores programs such as various settings, programs and data shown by flowcharts described later, and the RAM 112 is used as a work memory or the like.

  The key / indicator unit 25 includes a main key and an indicator provided in a main body case or the like, a lamp that is turned on when the projector 1 is started up, and the like. These indicators and the like are displayed and blinked by the control unit 11, and operation signals for various keys are sent to the control unit 11. The key operation signal from the remote controller is received by the Ir receiver 26, demodulated by the Ir processor 27, and the code signal is sent to the controller 11.

  The control unit 11 controls the light source control circuit 32 to perform time-division control on the red light source, the green light source, and the blue light source according to the image signal. Further, the cooling fan drive control circuit 33 performs temperature detection by a plurality of sensors provided in the light source device 20 and the like to control the rotation speed of the cooling fan, and cools the projector body even after the power is turned off by a timer or the like. Control of turning off the power of the projector main body is also performed depending on the result of temperature detection by the temperature sensor by continuing the rotation of the fan.

  The RAM 112 is preliminarily provided with areas for storing the remaining battery capacity N, which is the remaining capacity of the battery 29, the threshold value N1, and the threshold value N2. Here, the threshold value N1 is a lower limit voltage of the battery 29 in which the lamp of the light source device 20 can be turned on, that is, a lower limit voltage of the battery 29 in which the projector 1 can perform a projection operation. The threshold value N2 is calculated based on the threshold value N1. For example, the remaining amount of the battery 29 at which the lamp cannot be lit continuously after about 10 minutes, that is, about 10 minutes after the projector 1 is used. The voltage value of the battery 29 is less than the threshold value N1.

  In the present embodiment having the above-described configuration, the control unit 11 of the projector 1 executes processing as shown in the flowchart of FIG. 2 based on the program stored in the ROM 111 when the power is turned on. That is, when the power is turned on, the voltage of the battery 29 detected by the voltage detection circuit 28 is stored in the RAM 112 as the remaining battery charge N (step SA1). Next, it is determined whether or not the lamp of the light source device 20 is turned on (step SA2).

  When the lamp is lit, the remaining battery level N detected this time is compared with the threshold value N1 stored in the RAM 112 at this time, and it is determined whether or not the remaining battery level N is smaller than the threshold value N1 (step). SA3). If this determination is NO and the battery remaining amount N is equal to or greater than the threshold value N1, that is, the lamp is lit and the remaining battery amount N is greater than the threshold value N1 that is the lower limit voltage for lamp lighting. Therefore, the value of the threshold value N1 is appropriate and does not need to be corrected. Therefore, the process proceeds to step SA7 and image projection processing is executed without correcting the threshold value N1 by the processing in step SA5 described later.

  That is, the image data is converted by the image conversion unit 13, the image signal is developed and stored in the video RAM 18 by the display encoder 14, the video signal is generated from the stored contents of the video RAM 18, and is output to the display driving unit 15. . The display driving unit 15 drives the display element 19 in response to the transmitted image signal, and the light beam emitted from the light source device 20 is incident on the display element 19 via the light source side optical system, whereby display is performed. A light image is formed by the reflected light of the element 19, and a slide image is projected onto a screen (not shown) via the lens group 21.

  Further, since the power of the battery 29 is consumed by the image projection in this way, the remaining battery power N that decreases with this is detected again (step SA8). Subsequently, based on the threshold value N1, a threshold value N2 which is a remaining amount value of the battery 29 at which the lamp of the light source device 20 cannot be turned on after about 10 minutes is calculated (step SA9).

  That is, since the lamp rating of the light source device 20 in the projector 1 is known and the power consumption is known, the lamp cannot be continuously lit after about 10 minutes based on the power consumption of the lamp and the threshold value N1. It is possible to calculate the remaining value of the battery 29, that is, the voltage value of the battery 29 that becomes the threshold value N1 after about 10 minutes as the projector 1 is used. The calculated voltage value is stored in the RAM 112 as the threshold value N2.

  Subsequently, it is determined whether or not the battery remaining amount N detected during the projection operation in step SA8 has reached a level lower than the threshold value N2 (step SA10). If N <N2, that is, if the voltage of the battery 29 is equal to or higher than the threshold value N2, the process proceeds to step SA12 without performing the process in step SA11.

  In step SA12, it is determined whether or not a power-off operation has been performed, or whether or not the remaining amount of the battery 29 has become “0”. While the determination in step SA12 is NO, the processing from step SA7 is repeated. Therefore, the remaining amount N of the battery 29 gradually decreases with the projection operation. When the battery remaining amount N of the battery 29 reaches a level lower than the threshold value N2, the determination in step SA10 is YES. Accordingly, the process proceeds from step SA10 to step SA11, where the indicator of the key / indicator section 25 is operated to display a battery remaining amount warning (step SA11).

  At this time, as described above, the threshold value N2 is, for example, a battery remaining amount value in which the lamp of the light source device 20 is turned off after about 10 minutes when the projector 1 is continuously operated (continuous lighting is impossible). is there. Therefore, by visually recognizing the battery remaining amount warning display, the user can continuously use the projector 1 for only about 10 minutes and can perform projection, or cannot be projected in about 10 minutes. It is possible to recognize this, and a small amount of remaining battery power can be used systematically thereafter.

  On the other hand, if the result of determination in step SA2 is that the lamp has not turned on, it is determined whether or not the remaining battery capacity N is greater than a threshold value N1 (step SA4). If this determination is NO and (remaining battery power) N <N1 (threshold), that is, if the lamp does not light up and the remaining battery power N has reached a level lower than the threshold N1, The threshold value N1 is appropriate, but it is considered that the battery has not been sufficiently charged. After displaying a charge warning in step SA15, the power is turned off and the process is terminated.

  Further, when the determination in step SA4 is YES and N> N1, the lamp is not lit at the time of startup, but the battery remaining amount N is equal to or greater than the threshold value N1. In this case, the value of the threshold value N1 that has been set is smaller than the value of the remaining battery level N that could not be lit in step SA2.

  Thus, the reason why the value of the threshold value N1, which should be the lower limit voltage at which the lamp is lit, is actually smaller than the value of the remaining battery power N where the lamp could not be lit is This can be because the capacity of the battery 29 itself has become smaller due to the deterioration of the battery 29. That is, the threshold value N1 set before the capacity reduction of the battery 29 becomes smaller in evaluation value as the capacity of the battery 29 is reduced. Therefore, the threshold value N1 is actually lower than the lower limit voltage value at which the lamp can be turned on in step SA2. As described above, a phenomenon occurs in which the lamp cannot be lit even though the remaining battery charge N is larger than the threshold value N1. Therefore, it is necessary to increase the threshold value N1 whose evaluation value has decreased with the deterioration of the battery 29. In this case, the value of the remaining battery level N detected in step SA1 is replaced with the threshold value N1, and the threshold value is set. The value of N1 is increased (increased) (step SA5).

  Therefore, the threshold value N1 is variably set to a higher value as the deterioration of the battery 29 progresses.

  On the other hand, the case where the determination in step SA3 is YES is a case where N <N1 and the lamp is normally lit at the time of startup, but the remaining battery charge N is smaller than the threshold value N1. Here, although the remaining battery level N is smaller than the threshold value N1 that is the lower limit voltage for lighting the lamp, the lamp can be lit in step SA2, so the value of the threshold value N1 is inappropriate. There is a need to fix this.

  Further, as a cause of the phenomenon that the lamp can be turned on even though the value of the remaining battery level N detected in this way is smaller than the value of the threshold value N1, the process of step SA5 via step SA4 has been performed so far. Is performed several times, and it is assumed that there is an improvement in the deterioration of the battery 29 (for example, replacement of the battery) after the threshold value N1 is corrected to rise. That is, as described above, the evaluation value of the threshold value N1 can be appropriately maintained by performing the variable setting for increasing the value of the threshold value N1 in step SA5 via step SA4 in response to the deterioration of the battery 29. Since the capacity of the battery 29 itself increases as the deterioration is improved, the evaluation value of the threshold value N1 before the improvement of the deterioration of the battery 29 increases as the battery 29 deteriorates. In fact, it becomes larger than the lower limit voltage value at which the lamp can be lit, and as described above, a phenomenon occurs in which the lamp can be lit even though the remaining battery charge N is smaller than the threshold value N1. Therefore, it is necessary to lower the threshold value N1 whose evaluation value has increased due to the improvement of the deterioration of the battery 29. In this case, the value of the remaining battery power N detected in step SA1 is replaced with the threshold value N1. (Step SA5).

  However, in this case, the determination in step SA4 is YES, and in contrast to the case where the value of N1 is increased (increased) by replacing N with N1 in step SA5, N1 is replaced with N1. The value of is lowered (decreased).

  Accordingly, in step SA5, the threshold value N1 can be increased (increased) when the deterioration is progressing according to the deterioration state of the battery 29, and the threshold value N1 is increased (increased) more than the progress degree of the deterioration. ), That is, when the deterioration has improved from the state in which the deterioration has advanced and the threshold value N1 has been raised, the threshold value N1 can be lowered (decreased). That is, based on the fact whether or not the lamp is lit, it is determined whether or not the value of the threshold value N1, which is a preset lamp lighting lower limit voltage, is appropriate. The threshold value N1 is corrected.

  Next, it is determined whether or not the value of the threshold value N1 has decreased due to this replacement (step SA6). Here, the case where the value of the threshold value N1 is decreased is a case where the determination of the step SA2 is YES and the value of the threshold value N1 is variably set to decrease in the step SA5 via the step SA3. This is the case when it is lit. Therefore, if the determination in step SA6 is YES and the value of the threshold value N1 has decreased due to the replacement, the processing after step SA7 is executed as described above to perform image projection and the like.

  However, on the contrary, the case where the value of the threshold value N1 increases is a case where the determination in step SA2 is NO and the setting is made so that the value of the threshold value N1 is increased in step SA5 via step SA4. In this case, the lamp does not light up. Therefore, if the determination in step SA6 is NO and the value of the threshold value N1 increases due to the replacement, it is determined whether the increased N1 is less than a predetermined value (step SA13).

  When this determination is NO and the value of the threshold value N1 is larger than a predetermined value, it can be assumed that the battery 29 is considerably deteriorated. As described above, since the value of the threshold value N1 is variably set so as to increase in accordance with the deterioration of the battery 29 in step SA5, the degree of deterioration of the battery 29 is proportional to the value of the threshold value N1. It is because it becomes. Therefore, in this case, a battery deterioration warning is given by the key / indicator unit 25 (step SA14), the power is turned off, and the process is terminated. Accordingly, the user is prompted to replace the battery 29 by visually recognizing the battery deterioration warning, and can prevent the occurrence of a situation in which the battery runs out during projection and projection becomes impossible.

  On the other hand, if the determination in step SA13 is YES and the threshold value N1 is less than the predetermined value, the battery 29 has not deteriorated enough to require replacement, but the lamp is lit because the amount of charge is insufficient. It can be considered that it was not possible. Therefore, in this case, after a charging warning is given by the key / indicator unit 25 (step SA15), the power is turned off. Therefore, the user can recognize that the battery 29 is not deteriorated and can be used by charging by visually recognizing the charging warning, and unnecessary battery replacement can be prevented in advance.

  Further, as described above, the threshold value N2 is the remaining amount value of the battery 29 in which the lamp of the light source device 20 is turned off after about 10 minutes calculated based on the threshold value N1, and therefore the threshold value N1 is set according to the deterioration state of the battery 29. By appropriately increasing the value of the threshold value N1 as described above by increasing (increasing) the value or decreasing (decreasing) the battery 29 in accordance with improvement in deterioration. The value of the threshold value N2 is also corrected, and a more appropriate value can be calculated. Therefore, the projector 1 according to the present embodiment can issue a remaining amount warning of the battery 29 while suppressing the error of the remaining usable time (about 10 minutes) caused by the deterioration of the battery 29 and the improvement of the deterioration.

  In other words, the remaining amount warning can be appropriately performed according to the deterioration state of the battery 29.

(Modification of the first embodiment)
FIG. 3 is a flowchart showing a modification of the first embodiment. This flowchart is the same as the flowchart of FIG. 2 except for step SA5 among steps SA1 to SA15. However, in this modification, in the process of step SA5, a predetermined increase value α is added when the value of the battery remaining amount N is replaced with the value of the threshold value N1 and variably set. At this time, a positive value and a negative value are selectively used for “α”.

  That is, in the first embodiment described above, when the determination in step SA4 is YES and N> N1, the remaining battery level N is set to the threshold value N1 in step SA5, thereby increasing the value of the threshold value N1. (Increase) This is the fact that the lamp did not light in step SA2 even though the detected battery remaining amount N was larger than the preset threshold value N1. This is because it is estimated that the appropriate threshold value N1 is at least equal to or greater than the remaining battery level N. That is, since the appropriate threshold value N1 is a value equal to or greater than the remaining battery charge N, the threshold value N1 can be made closer to a more appropriate value by replacing the threshold value N1 with “N + α” in step SA5. . In this case, since the appropriate threshold value N1 is a value equal to or greater than the remaining battery charge N, a positive value is selected as the predetermined value α.

  On the other hand, in the first embodiment described above, when the determination in step SA3 is YES and N <N1, the value of the threshold N1 is decreased by setting the remaining battery capacity N to the threshold N1 in step SA5. (Decrease), but this is appropriate based on the fact that the lamp is lit in step SA2 even though the battery remaining amount N is smaller than the preset threshold value N1. This is because it is estimated that the value of the threshold value N1 will be at least the value of the remaining battery level N. In other words, since the appropriate threshold value N1 is equal to or less than the remaining battery level N, the threshold value N1 can be made closer to a more appropriate value by replacing the threshold value N1 with “N + α” in step SA5. . In this case, the battery predetermined value α is selected as a negative value.

  Therefore, according to this modification, the threshold value N1 can be made closer to the original value that is the lower limit voltage of the battery 29 that can be lit by the lamp of the light source device 20.

(Second Embodiment)
FIG. 4 is a flowchart showing a processing procedure in the second embodiment of the present invention. The control unit 11 of the projector 1 executes processing as shown in the flowchart of FIG. 4 based on the program stored in the ROM 111 when the power is turned on. In this flowchart, steps SB1 to SB15 are the same processing as steps SA1 to SA15 in the flowchart of FIG. 2 in the first embodiment. However, it differs from the first embodiment in that step SB16 is added.

  That is, if the result of determination in step SB2 is that the lamp has not turned on, it is determined whether or not the remaining battery capacity N is greater than the threshold value N1 (step SB4). When this determination is NO and (remaining battery amount) N <N1 (threshold value), that is, when the remaining battery amount N has already reached lower than the threshold value N1 at the time of activation, It is determined whether or not the absolute value | N−N1 | of the difference between the battery remaining amount N detected in step SB1 and a preset threshold value N1 is larger than a predetermined value (step SB16).

  If the determination in step SB16 is NO and the absolute value of the difference | N−N1 | is less than a predetermined value, the threshold value increases (increases) as the battery deteriorates as described above. Since the value of N1 is not so large, the deterioration of the battery 29 has not progressed so as to require replacement. However, since the lamp did not light, the deterioration of the battery 29 has not progressed so much as to require replacement, but it can be considered that the amount of charge is insufficient. Therefore, in this case, after giving a charging warning by the key / indicator unit 25 (step SB15), the power is turned off. Therefore, the user can recognize that the battery 29 is not deteriorated and can be used by charging by visually recognizing the charging warning, and unnecessary battery replacement can be prevented in advance.

  However, if the determination in step SB16 is YES and | N−N1 | is greater than or equal to a predetermined value, the value of the threshold value N1 that increases (increases) as the battery deteriorates as described above. Is considerably large, and it can be assumed that the deterioration of the battery 29 is progressing so as to require replacement. Therefore, in this case, the battery deterioration warning is given by the key / indicator unit 25 (step SB14), and then the power is turned off. Accordingly, the user is prompted to replace the battery 29 by visually recognizing the battery deterioration warning, and can prevent the occurrence of a situation in which the battery runs out during projection and projection becomes impossible.

  In this embodiment, the battery remaining amount warning is performed by display. However, the present invention is not limited to display, and the battery remaining amount warning may be performed by other means such as sound and warning sound.

  Further, in the present embodiment, when the determinations in steps SB4 and SB4 are NO and (remaining battery amount) N <N1 (threshold value), that is, the remaining battery amount N is already the threshold value N1 at the time of startup. If it has reached a lower level, the power is simply turned off and the process is terminated. However, immediately before turning off the power, the reason for turning off the power, that is, “the battery remaining amount N has already reached a lower level than the threshold N1 at the time of startup” may be notified. . Accordingly, the user can understand the reason why the power is turned off even when the power is turned on, and can prompt the user to charge or replace the battery before starting the projection.

  Furthermore, in the present embodiment, the case where the present invention is applied to a projector has been shown, but it is needless to say that the present invention is not limited to a projector and can be applied to various electronic devices that operate using a battery as a power source.

1 is a block diagram showing a circuit configuration of a projector according to an embodiment of the present invention. It is a flowchart which shows the process sequence in the 1st Embodiment of this invention. It is a flowchart which shows the process sequence in the modification of the 1st Embodiment of this invention. It is a flowchart which shows the process sequence in the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Projector 11 Control part 12 Input / output interface 13 Image conversion part 14 Display encoder 15 Display drive part 16 Input / output connector part 17 System bus 18 Video RAM
DESCRIPTION OF SYMBOLS 19 Display element 20 Light source device 21 Movable lens group 23 Image compression / expansion part 24 Memory card 25 Key / indicator part 28 Voltage detection circuit 29 Battery 111 ROM
112 RAM

Claims (8)

An electronic device that operates using a battery as a power source,
Storage means for storing a threshold value as a voltage value of the battery for driving the predetermined operation unit;
Detecting means for detecting a residual voltage value of the battery;
A comparison means for comparing the remaining voltage value of the battery with the threshold value;
Determination means for determining whether or not the predetermined operation unit has been driven;
A determination unit that determines a deterioration state of the battery based on a comparison result by the comparison unit and a determination result by the determination unit;
Threshold control means for variably setting the threshold value stored by the storage means in accordance with the deterioration state of the battery determined by the determination means;
An electronic device comprising: The electronic device according to claim 1 , wherein the threshold control unit replaces the threshold with a remaining voltage value of the battery based on a determination result of the determination unit. The electronic device according to claim 1 , wherein the threshold value control unit replaces the threshold value with a value obtained by adding a predetermined value α to the remaining voltage value of the battery based on a determination result of the determination unit. Electronic device of any of claims 1 to 3, based on the determination result, and performs the deterioration warning or charge warning of battery of said determination means. The determining means, based on the absolute value of the difference between the previous SL residual voltage value and the threshold value of the battery, the electronic equipment of any description of the claims 1 4, characterized in that to determine the deterioration state of the battery. A computer having an electronic device that operates using a battery as a power source, and a storage unit that stores a threshold value as a voltage value of the battery that drives the predetermined operation unit;
Detecting means for detecting a residual voltage value of the battery;
Comparison means for comparing the remaining voltage value of the battery with the threshold value,
Determination means for determining whether or not the predetermined operation unit has been driven;
A determination unit that determines a deterioration state of the battery based on a comparison result by the comparison unit and a determination result by the determination unit;
An electronic device control program that functions as threshold control means for variably setting the threshold stored by the storage unit in accordance with a battery deterioration state determined by the determination means.
A threshold setting method of an electronic device operating as a power source a battery having a storage unit that stores a threshold of a voltage of the battery for driving the predetermined operation section,
A detection step of detecting a residual voltage value of the battery;
A comparison step of comparing the remaining voltage value of the battery with the threshold value;
A determination step of determining whether or not the predetermined operation unit has been driven;
A determination step of determining a deterioration state of the battery based on a comparison result by the comparison step and a determination result by the determination step;
A threshold value setting method comprising: a threshold value control step for variably setting the threshold value stored by the storage unit in accordance with a battery deterioration state determined by the determination step. Wherein the predetermined operation unit, according to claim 1 to 7 or according to an electronic device, the electronic device control program, and a threshold setting method, which is a light source lamp.

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