JP2009152021A - Image projection device, light source lifetime prediction method of the image projection device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image projection device, enabling prediction as to when a light source would reach the end of its lifetime. <P>SOLUTION: The image projection device is equipped with the light source for projecting an image, and a light source lifetime predicting part for predicting when the light source would reach the end of its lifetime. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a video projection device and a light source lifetime prediction method for the video projection device.

  A light source (for example, a lamp) of a video projection apparatus (which will be described below using a projector as an example) has been improved in technology and has a long life. However, since the light emission brightness of the light source gradually decreases as the lifetime approaches, the projector user cannot use the light source at any time unless the light source is replaced at an appropriate timing.

  As a technology for detecting the timing of this light source replacement, for example, Patent Document 1 discloses a projection apparatus with a lamp life display function that improves the lamp wear detection accuracy by adding the lamp on-time stress time to the lamp use time. Disclosure. In this projector with a lamp life display function, when the count value of the lamp usage time reaches a certain value, the display unit gives a lamp consumption warning. Patent document 2 is disclosing the LED display apparatus which displays the fall degree of the light quantity of a light source lamp by an issuance color. Patent Document 3 discloses a projection type projector that projects a test pattern with all white or a specific color tone onto a screen, measures the luminance value of the projected test pattern with a luminance measurement unit, and compares it with a reference luminance value. is doing. The projection projector instructs replacement of the projection light source when the measured luminance level is lower than the reference value. Patent Document 4 discloses a projector that projects a test pattern of all black and color tones and displays a lamp life warning when the difference in luminance between all black and other tones falls below a specified value. Patent Document 5 discloses an illuminating device that counts and stores the number of times the lamp is attached and detached and the number of times the power is turned on, and determines that the life is reached when the specified number of times is reached.

  As a technique related to notification of lamp life, Patent Document 6 discloses an electronic still camera that notifies a cameraman of the remaining amount of power. Patent Document 7 discloses a brightness adjusting device that acquires the brightness of a light source in an LCD monitor or the like.

JP-A-8-106128 JP 10-165420 A JP 2000-147659 A JP 2006-171602 A JP 2006-236665 A JP-A-9-269523 Japanese Patent Laid-Open No. 2007-128827

  The technique described in the above-mentioned patent document is limited to warning the state of the light source at that time, for example, when the usage time has reached a certain value, regarding the life of the light source. And the technique described in the above-mentioned patent document cannot predict when the light source reaches the end of its life.

  The objective of this invention is providing the light source lifetime prediction method of the image projection apparatus and image projection apparatus which solve the said subject.

  The video projection apparatus includes a light source for projecting a video and a light source lifetime prediction unit that predicts when the light source reaches the lifetime.

  The light source lifetime prediction method of the image projection apparatus predicts when the light source for projecting an image reaches the lifetime.

  In the video projection device, it is possible to predict when the light source reaches the end of its life.

  Next, embodiments of the present invention will be described in detail with reference to the drawings. First, the configuration of the embodiment of the present invention will be described.

  FIG. 1 is a diagram illustrating a configuration of the projector 001. FIG. 1A is a diagram showing a schematic configuration of the projector 001 of the present invention, and FIG. 1B is a diagram showing a detailed configuration of the projector 001 of the present invention.

  Referring to FIG. 1A, the projector 001 includes a lamp unit 070 for projecting an image, and a lamp life prediction circuit 130 that predicts when the lamp unit 070 will reach the end of its life. According to the present invention, the projector 001 can predict when the lamp unit 070 will reach the end of its life.

  Referring to FIG. 1B, the projector 001 includes a power switch 010, a power circuit 011, a video input circuit 030, a lamp control circuit 040, a video irradiation control circuit 050, and a video irradiation unit 060. The projector 001 includes a lamp unit 070, a power switch management circuit 080, a luminance measurement circuit 090, a lamp life external display circuit 120, and a lamp life prediction circuit 130. Projector 001 can be referred to as a video projection device.

  The power switch 010 is a switch for switching whether or not the power supplied from the power outlet is supplied to the power circuit 011.

  The power supply circuit 011 is a circuit for supplying power to all the circuits. The power supply circuit 011 transforms power supplied from a power outlet outside the projector 001 and supplies it to each circuit.

  The video input circuit 030 is a circuit that captures video data from the outside of the projector 001 via a video external input (not shown).

  The lamp control circuit 040 is a circuit that controls the operation of the lamp unit 070 used as the light source of the projector 001.

  The image irradiation control circuit 050 is a circuit that performs control necessary for irradiating the image irradiation unit 060 with the image data input from the image input circuit 030.

  The image irradiation unit 060 is controlled by the image irradiation control circuit 050 and irradiates a screen (not shown) with the image transmitted from the image input circuit 030. The image irradiation unit 060 includes, for example, a liquid crystal element and a DMD (Digital Micromirror Device).

  The lamp unit 070 is a light source (consumable item) for the projector 001. The projector 001 projects the image irradiated on the image irradiation unit 060 on a screen (not shown) by the lamp of the lamp unit 070 emitting light. The lamp unit 070 has a unit configuration and includes a lamp and a relay circuit (not shown) inside. When the lamp unit 070 is new (hereinafter, “new” includes both the first time when the lamp unit 070 is new and the first time when it is replaced), the relay circuit (not shown) of the lamp unit 070 is turned on. It becomes OFF immediately after becoming. Thereafter, the relay circuit remains OFF until the lamp unit 070 is replaced. That is, the lamp unit 070 outputs a 1-pulse lamp replacement signal only when it is new. The luminance measuring circuit 090 described later inputs the lamp replacement signal.

  The power switch management circuit 080 is a circuit that calculates power switch management data for the power switch 010.

  The luminance measurement circuit 090 is a circuit that measures the luminance of the lamp unit 070 and converts it into data. When the lamp unit 070 is turned on, the luminance measurement circuit 090 is activated and measures the luminance of the lamp unit 070. The luminance measuring circuit 090 measures the luminance every certain time (for example, one hour) after the power is turned on. The luminance measurement circuit 090 inputs date and time data from a date management unit 821 of the power switch management circuit 080 described later. When the lamp unit 070 is new, the luminance measurement circuit 090 inputs a lamp replacement signal from the lamp unit 070.

  The luminance measurement circuit 090 outputs the measurement data to the data storage circuit 100. The measurement data includes a date, a time, a lamp replacement signal (only when the lamp unit 070 is new), and a luminance measurement value. In addition, the luminance measurement circuit 090 outputs the luminance measurement value to the lamp life analysis circuit 110.

  The lamp life prediction circuit 130 is a circuit that predicts when the lamp will reach the end of its life. The lamp life prediction circuit 130 includes a data storage circuit 100 and a lamp life analysis circuit 110. The lamp life prediction circuit 130 can be called a light source life prediction unit.

  The data storage circuit 100 is a storage circuit that accumulates measurement data measured by the luminance measurement circuit 090, power switch management data from the power switch management circuit 080, lamp life determination results from the lamp life analysis circuit 110, and the like. is there.

  The lamp life analysis circuit 110 is a circuit that analyzes the data in the data storage circuit 100 and predicts the lamp life. The lamp life analysis circuit 110 stores the life prediction result in the data storage circuit 100. The lamp life analysis circuit 110 outputs to the lamp life external display circuit 120 the lamp life determination result, the number of days (usable days) and the number of times (usable times) until the lamp unit 070 is replaced. The lamp life analysis circuit 110 can be called a light source life analysis unit.

  The lamp life external display circuit 120 displays the status of the lamp unit 070 and the lamp life determination result (data predicting when the lamp will reach the end of life (lamp replacement)) to display means (not shown) outside the projector 001. It is a circuit for displaying. The external display means is, for example, a liquid crystal display of the projector 001 main body, a display of a personal computer directly connected to the projector 001 via a cable or a network line.

  FIG. 2 is a diagram showing a configuration of the lamp life data table 101. The lamp life data table 101 includes, as items, a date 014, a time 015, a lamp replacement 016, a power supply SW017, a usage count 018 per day, a cumulative usage count 019, and a usage time 020 per time. Further, the lamp life data table 101 includes a brightness measurement value 021, a brightness change rate 022, and a lamp life determination result 023. The lamp life data table 101 includes the number of days 024 until the lamp replacement (the number of usable days from the present to the lamp replacement) and the number of times 025 until the lamp replacement (the number of usable times from the current to the lamp replacement).

  The date 014 indicates the date when the data is stored. Time 015 indicates the time when the data is stored. In the item of lamp replacement 016, “lamp replacement” is stored in the data storage circuit 100 when the lamp unit 070 in FIG. Specifically, when the lamp unit 070 is new, the measurement data output from the luminance measurement circuit 090 includes a lamp replacement signal, and the data storage circuit 100 inputs the lamp replacement signal. The data storage circuit 100 stores “lamp replacement” in the item of lamp replacement 016 of the lamp life data table 101. Further, when “lamp replacement” is stored in the item of the lamp life determination result 023, the data storage circuit 100 stores “lamp life” in the column of lamp replacement 016.

  The power SW 017 is turned on or off based on the power ON / OFF signal output from the power switch management circuit 080 that manages the operation of the power switch 010 in FIG. Indicates whether or not

  The use count 018 per day indicates the number of times the projector 001 has been used on the first day of the day.

  The cumulative use count 019 indicates the total number of times the user has used the projector 001 since the lamp unit 070 was new.

  The usage time 020 per time indicates the usage time for each time the projector 001 is used each time.

  The luminance measurement value 021 indicates the luminance measurement value of the lamp unit 070 measured by the luminance measurement circuit 090.

  The luminance change rate 022 indicates a luminance change rate that is a ratio of the luminance change amount to the luminance of the lamp when the lamp unit 070 is new, analyzed by the lamp life analysis circuit 110.

  The lamp life determination result 023 indicates the life determination result of the lamp unit 070 analyzed by the lamp life analysis circuit 110.

  The number of days until lamp replacement 024 indicates the number of usable days from the present time analyzed by the lamp life analysis circuit 110 to the replacement of the lamp unit 070.

  The number of times 025 until the lamp replacement indicates the number of usable times from the present time analyzed by the lamp life analysis circuit 110 to the replacement of the lamp unit 070.

  In FIG. 2, the measured luminance value 026 “1300” is a numerical value of the luminance when the lamp life analysis circuit 110 determines that the lamp is worn, and the measured luminance value 027 “1000” requires lamp replacement. It is the numerical value of the luminance at the time. The luminance measurement value 028 “2000” is a numerical value (luminance at the time of a new article) measured for the first time after the lamp is replaced. The cumulative usage count 029 “430th” is a numerical value of the cumulative usage count 019 when the lamp life analysis circuit 110 determines that the lamp is worn.

  FIG. 3 is a diagram showing the configuration of the power switch management circuit 080. As shown in FIG. The power switch management circuit 080 includes an ON / OFF input unit 081, a daily usage number counter 082, a cumulative usage number counter 083, a usage time timer 084 per time, and an output unit 085.

  The ON / OFF input unit 081 receives a power ON signal (indicating that the power has been turned on from OFF) or a power OFF signal (indicating that the power has been turned off from ON) from the power switch 010. Then, the ON / OFF input unit 081 outputs a power ON signal to the daily usage counter 082, the cumulative usage counter 083, the per-time usage timer 084, and the output unit 085.

  The daily usage counter 082 includes a counter 820, a date management unit 821, a latest usage date storage unit 822, and a comparison unit 823.

  The counter 820 is a counter for counting the number of times the projector 001 is used per day. Each time a power ON signal is input, 1 is added. When the comparison unit 823 determines that the date at that time is different from the date stored in the latest use date storage unit 822, the counter 820 is reset and incremented by one.

  The date management unit 821 is a clock that holds the date and time at that time. The date management unit 821 outputs date and time data to the luminance measurement circuit 090 via the output unit 085.

  The latest use date storage unit 822 stores the date when the projector 001 was most recently used.

  The comparison unit 823 compares whether the current date held by the date management unit 821 and the date most recently used by the projector 001 held by the latest use date storage unit 822 are the same.

  The cumulative use count counter 083 is a counter for counting the cumulative use count of the projector 001. When the power ON signal is input, the cumulative use count counter 083 is incremented by one.

  The use time timer 084 is a timer for measuring the use time of the projector 001 once, and starts when a power ON signal is input, and stops and resets when a power OFF signal is input.

  The output unit 085 is an output unit for outputting data to the data storage circuit 100 and the luminance measurement circuit 090. The output unit 085 receives the power ON signal from the ON / OFF input unit 081, the daily usage count from the daily usage counter 082, and the cumulative usage count from the cumulative usage count counter 083, and outputs it to the data storage circuit 100. . The output unit 085 receives date and time data from the date management unit 821 and outputs the date and time data to the luminance measurement circuit 090.

  FIG. 4 is a diagram showing a configuration of the lamp life analysis circuit 110.

  The lamp life analysis circuit 110 includes an input unit 111, a lamp life determination unit 112, a luminance change rate calculation unit 113, a lamp life calculation unit 114, and an output unit 115.

  The input unit 111 inputs data from the luminance measurement circuit 090 or the data storage circuit 100 and transfers the data to each unit in the lamp life analysis circuit 110.

  The lamp life determination unit 112 includes a comparison unit 200 and a threshold storage unit 201.

  The comparison unit 200 compares the luminance measurement value from the luminance measurement circuit 090 with the first numerical value or the second numerical value stored in the threshold storage unit 201 in advance, thereby performing “lamp replacement”, “lamp wear”, “ The lamp life is judged as “No abnormality”.

  The threshold storage unit 201 is a storage unit that stores the first numerical value and the second numerical value. The first numerical value and the second numerical value are values obtained by multiplying the brightness of the lamp unit 070 used in the projector 001 when it is new by a certain ratio. The first numerical value and the second numerical value are preset in accordance with the lamp life determination.

  The luminance change rate calculation unit 113 compares the first measurement value after the lamp unit 070 is replaced with the latest luminance measurement value from the luminance measurement circuit 090. Then, the luminance change rate calculation unit 113 calculates the change amount of the numerical value, and calculates the change rate at that time (the ratio of the change amount to the first measured value after the lamp unit 070 is replaced).

  The lamp life calculation unit 114 includes a luminance change (past) calculation unit 400, a luminance change (future) calculation unit 401, a use day calculation unit 402, a cumulative use count input unit 403, and a lamp replacement. A day number calculation unit 406 and a number calculation unit 407 until lamp replacement are included. The function of each part is performed in the description of the operation of FIG.

  This is the end of the description of the configuration of the embodiment of the present invention.

  Next, the operation of the embodiment of the present invention will be described with reference to the drawings.

  When the power switch 010 is turned on in FIG. 1B, an external power outlet supplies power to the power switch 010. The power switch 010 supplies power to the video input circuit 030, the video irradiation control circuit 050, and the lamp control circuit 040 via the power circuit 011. The lamp control circuit 040 supplies power to the lamp unit 070. The lamp unit 070 is turned on when power is supplied from the lamp control circuit 040.

  When the power switch 010 is turned ON or OFF, the power switch 010 sends a power ON signal or a power OFF signal to the power switch management circuit 080.

  FIG. 5 is a flowchart showing the operation of the power switch management circuit 080. First, a case where the power switch management circuit 080 inputs a power ON signal will be described with reference to FIGS. 3 and 5A.

  The ON / OFF input unit 081 receives a power ON signal, and outputs a power ON signal to the daily usage counter 082, the cumulative usage counter 083, the per-time usage timer 084, and the output unit 085. (A1). The comparison unit 823 determines whether the date is the same as the latest use date (A2). That is, the comparison unit 823 reads the date when the power ON signal is input from the date management unit 821, and reads the latest use date that is the date the projector 001 was most recently used from the latest use date storage unit 822. Then, the comparison unit 823 compares the date when the power ON signal is input with the latest use date. When the date when the power ON signal is input is not the same as the latest use date (A2, No), the latest use date storage unit 822 updates the latest use date to the date when the power ON signal is input (A3). Then, the daily usage counter 082 resets the counter 820 (A4). If the date at that time is the same as the latest use date (A2, Yes), this operation skips steps A3 and A4 and proceeds to step A5.

  The daily usage counter 082 adds 1 to itself (A5). That is, the daily usage counter 082 adds 1 to the counter 820. Next, the cumulative use number counter 083 adds 1 to itself (A6). Next, the operation time timer 084 starts once (A7). The output unit 085 receives the power ON signal from the ON / OFF input unit 081, the daily usage count from the daily usage counter 082, and the cumulative usage count from the cumulative usage count counter 083, and outputs it to the data storage circuit 100. (A8).

  Next, a case where the power switch management circuit 080 inputs a power OFF signal will be described with reference to FIGS. 3 and 5B.

  The ON / OFF input unit 081 inputs a power OFF signal (B1). Then, the use time timer 084 per operation stops the operation (B2). The output unit 085 receives the power-off signal from the ON / OFF input unit 081, the usage time from the usage time timer 084 per time, and outputs it to the data storage circuit 100 (B3). The one-time use time timer 084 resets its own one-time use time timer 084 (B4).

  The date management unit 821 outputs date and time data to the luminance measurement circuit 090 via the output unit 085 separately from the above operation.

  The operation of the embodiment of the present invention will be described again with reference to FIG. The data storage circuit 100 stores the data input from the power switch management circuit 080 in the lamp life data table 101 of FIG. Specifically, the data storage circuit 100 stores ON / OFF in the item of the power SW 017 based on the power ON signal and the power OFF signal. Similarly, the data storage circuit 100 stores the data of the number of times of use per day in the item of number of times of use 018 per day, stores the data of the total number of times of use in the item of the number of times of cumulative use 019, and indicates the usage time when the power is turned off. Data is stored in the item of use time 020 per time.

  The video input circuit 030 can capture video from an external video input after receiving power from the power supply circuit 011. The video input circuit 030 converts the captured video into data used in the projector 001 and outputs the data to the video irradiation control circuit 050. The image irradiation control circuit 050 receives the data output from the image input circuit 030 after receiving the power supply from the power supply circuit 011 and controls data necessary for irradiating the data to the outside and image data that can be irradiated. And is sent to the image irradiation unit 060. The image irradiation unit 060 receives control data and image data sent from the image irradiation control circuit 050, and uses the light of the lamp unit 070 to irradiate an image on a screen (not shown) outside the projector 001. Here, when power is supplied to the lamp unit 070 when the lamp unit 070 is new, the relay circuit (not shown) of the lamp unit 070 is turned on and then immediately turned off. Thereafter, the relay circuit remains OFF until the lamp unit 070 is replaced. That is, the lamp unit 070 outputs a one-pulse lamp replacement signal to the luminance measurement circuit 090 only when it is new.

  When the lamp unit 070 is turned on, the luminance measurement circuit 090 is activated and measures the luminance of the lamp unit 070. Also, the luminance measurement circuit 090 measures the luminance every certain time (for example, one hour) after the power is turned on. The luminance measurement circuit 090 inputs date and time data from the date management unit 821 of the power switch management circuit 080. When the lamp unit 070 is new, the luminance measurement circuit 090 inputs a lamp replacement signal from the lamp unit 070.

  The luminance measurement circuit 090 outputs the measurement data to the data storage circuit 100. The measurement data includes a date, time, a lamp replacement signal (only when the lamp unit 070 is new), and a luminance measurement value. In addition, the luminance measurement circuit 090 outputs the luminance measurement value to the lamp life analysis circuit 110. The data storage circuit 100 stores the measurement data output from the luminance measurement circuit 090 in the lamp life data table 101 of FIG. The data storage circuit 100 stores the date data in the date 014 item, the time data in the time 015 item, and when the lamp replacement signal is received, the lamp replacement data in the lamp replacement 016 item. Is stored in the item of the luminance measurement value 021. When the lamp life analysis circuit 110 receives the brightness measurement value, the lamp life analysis circuit 110 determines the life of the lamp unit 070 based on the brightness measurement value.

  FIG. 6 is a flowchart showing the operation of the lamp life analysis circuit 110. The lamp life analysis circuit 110 compares the brightness measurement value when the lamp unit 070 is new and the latest brightness measurement value (C1). That is, the comparison unit 200 compares the input luminance measurement value with the first numerical value stored in the threshold storage unit 201 in advance. The first numerical value is, for example, 65% of the brightness when the lamp unit 070 used in the projector 001 is new. When the values shown in FIG. 2 are described in association with each other, the brightness when new is “2000” of the brightness measurement value 028 of the lamp life data table 101, and 65% of the brightness when new is the brightness measurement value 026. The value of “1300”. Then, the comparison unit 200 determines whether or not the latest brightness measurement value is 65% or less of the brightness when new (C2).

  When the brightness is 65% or less of the new brightness (C2, Yes), the comparison unit 200 determines whether the latest brightness measurement value is 50% or less of the brightness when new (C3). That is, the comparison unit 200 compares the input luminance measurement value with the second numerical value stored in advance in the threshold storage unit 201. The second numerical value is, for example, 50% of the brightness when the lamp unit 070 used in the projector 001 is new. Referring to the values shown in FIG. 2 in association with each other, 50% of the brightness when new is a value of “1000” of the brightness measurement value 027. A value of 50% can generally be referred to as the light source exchange luminance rate.

  When the brightness is greater than 65% of the new brightness (C2, No), the output unit 115 stores and outputs “no abnormality” (C9). That is, the comparison unit 200 outputs “no abnormality” to the output unit 115. Then, the output unit 115 outputs the lamp life determination result “no abnormality” to the data storage circuit 100 and the lamp life external display circuit 120. The data storage circuit 100 stores “no abnormality” in the lamp life determination result 023 of the lamp life data table 101. The lamp life external display circuit 120 displays “no abnormality” on display means (display or the like) outside the projector 001.

  When the brightness is 50% or less of the new brightness (C3, Yes), the output unit 115 stores and outputs “Lamp replacement” (C7). That is, the comparison unit 200 outputs “Lamp replacement” to the output unit 115. Then, the output unit 115 outputs a lamp life determination result “lamp replacement” to the data storage circuit 100 and the lamp life external display circuit 120. The data storage circuit 100 stores “lamp replacement” in the lamp life determination result 023 of the lamp life data table 101 and stores “lamp life” in the lamp replacement 016. The lamp life external display circuit 120 displays “Lamp replacement” on display means (display or the like) outside the projector 001. In this example, a numerical value of 50% (lamp replacement luminance rate) or less indicates that the lamp has reached the end of its life, and indicates that the projector 001 cannot be used unless the lamp unit 070 is replaced.

  When the brightness is greater than 50% of the new brightness (C3, No), the output unit 115 stores and outputs “lamp wear” (C4). In this example, a luminance of 65% or less and greater than 50% indicates that the lamp unit 070 is worn (consumed), although the lamp is not replaced.

  As described above, based on the first numerical value and the second numerical value, the life determination of the lamp unit 070 is determined in three stages. The determination is “no abnormality”, “lamp wear”, and “lamp replacement”. .

  Subsequently, the luminance change rate calculation unit 113 calculates and stores the luminance change rate (C8, C5, C10). That is, the luminance change rate calculation unit 113 takes out the first measurement value after replacing the lamp unit 070 (the luminance measurement value 021 “2000” in FIG. 2). Then, the luminance change rate calculation unit 113 compares the latest luminance measurement value sent from the luminance measurement circuit 090, calculates the change amount of the numerical value, and calculates the change rate at that time. Specifically, the luminance change rate calculation unit 113 subtracts the latest luminance from the new luminance and divides the value obtained by the subtraction by the new luminance to obtain the luminance change rate (the luminance change amount). Calculate the ratio to the brightness when new. Then, the output unit 115 outputs the luminance change rate to the data storage circuit 100. The data storage circuit 100 stores the luminance change rate in the item of the luminance change rate 022 of the lamp life data table 101.

  When the process of step C5 is completed, the lamp life calculation unit 114 calculates the lamp life (number of lamp replacements, days), and stores and outputs it (C6). When the processes of steps C8, C6, and C10 are completed, the lamp life analysis circuit 110 ends the operation.

  Hereinafter, the operation of step C6 will be described. FIG. 7 is a flowchart showing the operation of step C6 in FIG. The lamp life calculation unit 114 performs calculation based on the values stored in the lamp life data table 101 to predict the lamp life.

  First, the luminance change (past) calculation unit 400 subtracts the latest luminance from the new luminance of the lamp unit 070 to calculate the luminance change (past) (D1). For example, in the present embodiment, the luminance change amount (past portion) calculation unit 400 subtracts the luminance measurement value 026 “1300” from the luminance measurement value 028 “2000” to obtain the luminance change amount (past portion) (A). calculate.

  Then, the luminance change amount (for future) calculation unit 401 replaces the lamp unit 070 obtained by multiplying the newest luminance of the lamp unit 070 by the new luminance of the lamp unit 070 and the replacement luminance rate of the lamp unit 070. Subtract luminance. Thereby, the luminance change amount (for future) calculation unit 401 calculates the luminance change amount (for future) (D2). For example, in the present embodiment, the luminance change amount (for the future) calculation unit 401 calculates the lamp obtained by multiplying the luminance measurement value 026 “1300” by the luminance measurement value 028 “2000” and the exchange luminance ratio 50%. Subtract unit 070 exchange brightness. Thereby, the luminance change amount (for future) calculation unit 401 calculates the luminance change amount (for future) (B).

  Then, the use day calculation unit 402 subtracts the date when the lamp unit 070 is new from the latest date to calculate the use day (D3). For example, in the present embodiment, the number of days used calculation unit 402 is H.264. 19.10.1 is subtracted from H19.8.29 to calculate the number of days used (C).

  Then, the cumulative usage count input unit 403 inputs the cumulative usage count since the lamp unit 070 is new (D4). For example, in the present embodiment, the cumulative usage count input unit 403 inputs the cumulative usage count 029 “430” (D) from the lamp life data table 101 of the data storage circuit 100.

  Next, the number-of-days calculation unit 406 until lamp replacement multiplies the value obtained by dividing the luminance change amount (future portion) by the luminance change amount (past portion) by the number of days used. Accordingly, the number of days until lamp replacement unit 406 calculates the (usable) number of days until the lamp unit 070 replacement (the number of days until the lamp unit 070 reaches the end of its life) (D5). For example, in the present embodiment, the number of days until lamp replacement 406 calculates the number of days until replacement of the lamp unit 070 by multiplying the value obtained by dividing (B) by (A) by (C). The number-of-days calculator 406 until lamp replacement can be referred to as the number of days until the light source lifetime.

  The number calculation unit 407 until lamp replacement multiplies the value obtained by dividing the luminance change amount (future amount) by the luminance change amount (past portion) by the number of times of use. As a result, the number-of-times calculating section 407 until the lamp replacement calculates the (usable) number of times until the lamp unit 070 is replaced (the number of times the lamp unit 070 can be used until the end of its life) (D6). For example, in the present embodiment, the number of times until lamp replacement 407 calculates the number of times until the lamp unit 070 is replaced by multiplying the value obtained by dividing (B) by (A) by (D). The number calculation unit 407 until lamp replacement can be called a number calculation unit until the light source lifetime.

  The output unit 115 outputs the lamp life prediction result (the number of days and the number of times until the lamp unit 070 replacement) obtained by the lamp life calculation unit 114 to the data storage circuit 100 and the lamp life external display circuit 120. The data storage circuit 100 stores the lamp life prediction results in the items of the number of days until lamp replacement 024 and the number of times 025 until lamp replacement in the data life data table 101. The lamp life external display circuit 120 displays the lamp life judgment result “lamp wear” and the number of days until the lamp replacement and the number of times until the lamp replacement on display means (display or the like) outside the projector 001. Above, description of operation | movement of step C6 is complete | finished.

  Above, description of operation | movement of embodiment of this invention is complete | finished.

  In the present embodiment, the calculation is performed for both the number of days until the lamp replacement and the number of times until the lamp replacement.

  Next, effects in the embodiment of the present invention will be described.

  The present invention has an effect that the projector 001 can predict when the lamp unit 070 will reach the end of its life. This is because the projector 001 includes a lamp life prediction circuit 130 that predicts when the lamp unit 070 will reach the end of its life.

  For example, the user of the projector 001 determines the number of days until the lamp unit 070 reaches the end of its life (number of days until lamp replacement 024) and the number of times until the lamp unit 070 reaches the end of life (until the lamp replacement). The number of times 025) can be known.

  As a result, the user can automatically and specifically know the number of usable days and the number of times, so that the user can determine when to purchase the replacement lamp unit 070 and stock the replacement lamp unit 070. The number of days to leave can be reduced. In the case of the projector 001 that informs the user only of the remaining usable time, the user needs to calculate the amount of change in luminance (past and future) in order to know how many days and months the user can use. It becomes. Further, it is necessary for the user to collect data such as the number of days used and the total number of times of use from around the day. These calculations and collections are troublesome for the user.

  Further, the user can prevent the projector 001 from being unusable when the lamp unit 070 reaches the end of its life in the absence of the replacement lamp unit 070.

  The present invention has an effect that, for example, the user can reduce the use cost by using up the lamp unit 070, and at the same time, the resources can be effectively used. The reason is that it is possible to predict when the lamp unit 070 will reach the end of its life. Therefore, when the present invention is not applied, the lamp unit 070 that has been preliminarily replaced by the user before the end of the life is replaced. This is because it can be used up when the invention is applied.

  The present invention has an effect that, for example, the recovery time when the projector 001 fails can be shortened. The reason is that according to the present invention, failure analysis can be performed by analyzing data stored in the lamp life data table 101 of the data storage circuit 100.

  For example, normally, the brightness measurement value 021 of the lamp unit 070 decreases as the usage time of the projector 001 elapses. However, if it is found as a result of data analysis that the luminance measurement value 021 is fluctuating, the user or maintenance staff can predict the malfunction of the lamp unit 070, the power supply circuit 011 and the like. Further, in the case of the projector 001 having a very large number of times and times of use, the user can determine that the projector 001 has reached the end of its life and replace the projector 001 main body without replacing the lamp unit 070.

  As a result, the present invention can shorten the time required for fault isolation and shorten the result recovery time as compared with the case where fault isolation is performed in the absence of data stored in the lamp life data table 101. Can do.

It is a figure which shows the structure of the projector 001. It is a figure which shows the structure of the lamp life data table. 2 is a diagram showing a configuration of a power switch management circuit 080. FIG. 2 is a diagram illustrating a configuration of a lamp life analysis circuit 110. FIG. 5 is a flowchart showing the operation of a power switch management circuit 080. 5 is a flowchart showing the operation of the lamp life analysis circuit 110. 6 is a flowchart showing the operation of step C6 in FIG.

Explanation of symbols

001 Projector 010 Power switch 011 Power supply circuit 030 Video input circuit 040 Lamp control circuit 050 Video irradiation control circuit 060 Video irradiation unit 070 Lamp unit 080 Power switch management circuit 081 ON / OFF input unit 082 Daily usage counter 820 Counter 821 Date Management unit 822 Latest usage date storage unit 823 Comparison unit 083 Cumulative usage count counter 084 Usage time timer per operation 085 Output unit 090 Luminance measurement circuit 100 Data storage circuit 101 Lamp life data table 014 Date 015 Time 016 Lamp replacement 016 Power switch SW
018 Number of times of use per day 019 Cumulative number of times of use 020 Time of use per time 021 Luminance measurement value 022 Luminance change rate 023 Lamp life judgment result 024 Days until lamp replacement 025 Number of times until lamp replacement 026 Luminance measurement value 027 Luminance measurement value 028 Luminance Measured value 029 Cumulative usage number 110 Lamp life analysis circuit 111 Input unit 112 Lamp life determination unit 200 Comparison unit 201 Threshold storage unit 113 Luminance change rate calculation unit 114 Lamp life calculation unit 400 Luminance change amount (past) calculation unit 401 Luminance change Amount (future part) calculation unit 402 Days of use calculation unit 403 Cumulative usage count input unit 406 Days until lamp replacement 407 Number of times until lamp replacement 115 Output unit 120 Lamp life external display circuit 130 Lamp life prediction circuit

Claims (10)

A light source for projecting an image;
An image projection apparatus comprising: a light source life prediction unit that predicts when a light source reaches the end of its life. The light source life prediction unit
The image projection apparatus according to claim 1, further comprising: a light source life analysis unit that calculates the number of days until the light source reaches the end of life or the number of times until the light source reaches the end of life. The light source life analysis unit is
A luminance conversion amount (past part) calculating unit that subtracts the latest luminance from the luminance of the light source when it is new and calculates a luminance change amount (past part);
A luminance change amount for calculating a luminance change amount (for the future) by subtracting the light source replacement luminance obtained by multiplying the new light source luminance and the light source replacement luminance ratio from the latest luminance of the light source. Including future calculation) and
The image projection according to claim 2, wherein the number of days until the light source reaches the end of life or the number of times until the light source reaches the end of life is calculated based on the amount of change in luminance (for the past) and the amount of change in brightness (for the future). apparatus. The light source life analysis unit is
Subtract the date when the light source is new from the latest date, and calculate the number of days used,
A number of days until a light source lifetime for calculating the number of days until the light source reaches the end of life by multiplying the value obtained by dividing the amount of brightness change (for the future) by the amount of brightness change (the past amount) and the number of days used; The video projection device according to claim 3, comprising: The light source life analysis unit is
A cumulative usage count input section for inputting the cumulative usage count since the new light source;
Multiplying the luminance change amount (future part) by the luminance change amount (past part) and the cumulative number of times of use, and calculating the number of times until the light source reaches the end of its life, The video projection device according to claim 3 or 4 including these. A method for predicting the light source life of a video projection apparatus that predicts when the light source for projecting an image will reach the end of its life. The prediction is
The light source lifetime prediction method of the video projector according to claim 6, comprising calculating the number of days until the light source reaches the end of life or the number of times until the light source reaches the end of the lifetime. Subtract the latest brightness from the brightness of the light source when it is new, and calculate the brightness change amount (past).
From the latest brightness of the light source, subtract the light source replacement brightness obtained by multiplying the brightness of the light source when it is new and the replacement brightness rate of the light source, and calculate the amount of brightness change (for the future),
The light source lifetime according to claim 7, wherein the number of days until the light source reaches the lifetime or the number of times until the light source reaches the lifetime is calculated based on the luminance change amount (past portion) and the luminance change amount (future portion). Prediction method. Subtract the date when the light source is new from the latest date, calculate the number of days used,
The video projection according to claim 8, wherein the number of days until the light source reaches the end of life is calculated by multiplying the value obtained by dividing the luminance change amount (future portion) by the luminance change amount (past portion) and the number of days used. Method for predicting the light source lifetime of an apparatus. Enter the total number of times the light source has been used since it was new,
10. The number of times until the light source reaches the end of its life is calculated by multiplying a value obtained by dividing the luminance change amount (future portion) by the luminance change amount (past portion) and the cumulative number of times of use. Method for predicting the light source lifetime of a video projection apparatus.

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