JP2014066963A - Adapter, projector, and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve an on/off pattern in which one of a lighting device and a projector is turned on and the other is turned off, by only switching one common switch in the case that the lighting device and the projector are electrically connected to a power source via the one common switch.SOLUTION: An adapter includes: a first terminal which is supplied with power from the outside; a second terminal which is electrically connected to a power receiving terminal of a lighting device or a projector; a selection unit which selects one of power supply and shutdown in accordance with a cyclic rule at each time of the start of supply of the power to the first terminal; and a supply circuit which supplies the power to the second terminal when power supply is selected by the selection unit, but does not supply the power to the second terminal when shutdown is selected by the selection unit.

Description

  The present invention relates to an adapter, a projector, and a control method thereof.

  The projector shown in FIG. 7 is coupled to a socket that supplies power to a lighting device (Patent Documents 1 and 2).

JP 2005-99588 A JP 2006-227143 A

  For example, in homes, offices, and stores, a plurality of lighting devices may be wired together (or in the same phase) using a common switch. When one of a plurality of illumination devices wired in this way is replaced with a projector, the ON / OFF state is always the same between the illumination device and the projector. Then, as it is, for example, when the user wants to use the projector with the lighting device turned off, it is necessary to separately prepare a switch for the lighting device. It is not convenient for the user. Note that the projector being in the ON state includes both the case where the driving of the light source unit is started and the case where the projector is set in the standby state.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 According to an aspect of the present invention, the adapter includes a first terminal to which electric power is supplied from the outside, a second terminal electrically connected to the power receiving terminal of the lighting device or the projector, Each time the electric power starts to be supplied to the first terminal, a selection unit that selects either energization or interruption according to a cyclic rule, and the power when the energization is selected by the selection unit And a supply circuit that does not supply the power to the second terminal when the selection is selected by the selection unit.

  Application Example 2 According to another aspect of the present invention, the projector energizes and shuts off each time the power starts to be supplied to the power receiving terminal, the power supply unit, and the power receiving terminal to which power is supplied from the outside. A selection unit that selects either one of them according to a cyclic rule, and when the selection unit selects the energization, the power is supplied to the power supply unit, and the selection unit selects the cutoff. And a supply circuit that does not supply the power to the power supply unit. And when the said power supply part receives supply of the said electric power, the said projector will be in an ON state.

  Application Example 3 According to still another aspect, the projector further includes a light source unit, and the ON state is a state in which the light source unit emits light.

  Application Example 4 According to still another aspect, the ON state is a standby state.

  Application Example 5 According to another aspect of the present invention, a method for controlling a projector having a power receiving terminal to which power is supplied from the outside is turned on and off each time power is started to be supplied to the power receiving terminal. A selection step of selecting one of them according to a cyclic rule, and when the energization is selected in the selection step, the projector is turned on, and the cutoff is selected in the selection step And a step of not turning on the projector.

  Application Example 6 According to still another aspect, the projector further includes a light source unit, and the ON state is a state in which the light source unit emits light.

  Application Example 7 According to still another aspect, the ON state is a standby state of the projector.

  According to the above configuration, even if the lighting device and the projector are electrically connected to the power supply through a common switch, one of the lighting devices and the projector is turned on by opening and closing the common switch. ON / OFF pattern that turns OFF can be realized.

The schematic diagram which shows the usage example of the adapter in the illumination set 1 of Embodiment 1. FIG. FIG. 3 is a schematic diagram of an adapter according to the first embodiment. 5 is a flowchart showing processing in the adapter according to the first embodiment. 5 is a flowchart showing processing in the adapter according to the first embodiment. FIG. 6 is a schematic diagram of a projector according to a second embodiment. 10 is a flowchart showing processing of an adapter according to the third embodiment. (A) And (B) is a side view which shows the projector which concerns on background art.

(Embodiment 1)
As shown in FIG. 1, the adapters 2 </ b> A and 2 </ b> B of the present embodiment are used in an “illumination set 1” in which a projector 100 that projects image light and an illumination device 200 that emits illumination light coexist. The illumination set 1 includes a projector 100, an illumination device 200, two adapters 2A and 2B, two power supply terminals 20A and 20B, a power line 40, and a switch 50. Power is supplied to the power supply terminals 20 </ b> A and 20 </ b> B from an external 100 V (60 Hz or 50 Hz) power supply 60 via the power line 40. Here, the power line 40 is controlled so that power supply from the power source 60 to the projector 100 and power supply from the power source 60 to the lighting device 200 are controlled by opening and closing one common switch 50. Wired. The projector 100 can also function as a lighting device by projecting, for example, white plain image light.

  The adapter 2A is connected between the power supply terminal 20A and the projector 100. Specifically, the adapter 2A includes a terminal 3A and a terminal 7A. The terminal 3A is connected to the power supply terminal 20A, and the terminal 7A is connected to a power receiving terminal 101 (described later) of the projector 100.

  The adapter 2B is connected between the power supply terminal 20B and the lighting device 200. Specifically, the adapter 2B includes a terminal 3B and a terminal 7B. The terminal 3B is connected to the power supply terminal 20B, and the terminal 7B is connected to a power receiving terminal 202 (described later) of the lighting device 200. .

  The projector 100 has a power receiving terminal 101. The power receiving terminal 101 of this embodiment is a base. By connecting the power receiving terminal 101 to the power feeding terminal 20A or the terminal 7A of the adapter 2A, the projector 100 is fixed to the power feeding terminal 20A or the terminal 7A. Then, power for operating the projector 100 can be supplied to the projector 100 from the power supply terminal 20A or the terminal 7A.

  The lighting device 200 has a power receiving terminal 202. The power receiving terminal 202 of this embodiment is a base of the same type as the power receiving terminal 101 of the projector 100. The lighting device 200 is fixed to the power supply terminal 20B or the terminal 7B by coupling the power reception terminal 202 to the power supply terminal 20B or the terminal 7B of the adapter 2B. Then, electric power for lighting the lighting device 200 can be supplied to the lighting device 200 from the power supply terminal 20B or the terminal 7B. Note that the lighting device 200 of the present embodiment is an LED bulb.

  The configuration of the adapter 2A and the configuration of the adapter 2B are basically the same. For this reason, below, the structure of the adapter 2A is demonstrated for convenience.

  As shown in FIG. 2, the adapter 2A includes a terminal 3A, a supply circuit 4, a selection unit 5, a secondary battery 6, and a terminal 7A. The terminal 3A and the terminal 7A can be electrically connected to each other via the supply circuit 4. The supply circuit 4 electrically connects or disconnects the terminal 3A and the terminal 7A in accordance with the control from the selection unit 5. The supply circuit 4 includes a relay circuit, and the function (described later) of the supply circuit 4 is realized by the relay circuit.

  The selection unit 5 includes a control unit 8 and a storage unit 9, and functions by power supplied from the supply circuit 4. The control unit 8 includes a CPU. The storage unit 9 includes a RAM and a rewritable nonvolatile memory. A software program and data are written in the storage unit 9, and the CPU of the control unit 8 executes the software program based on the data, so that a function to be described later as the selection unit 5 (FIGS. 3 and 3). 4) is realized. The configuration of the selection unit 5 is not limited to such a form, and may be realized by dedicated hardware including a flip-flop circuit.

  The secondary battery 6 is charged with power from the supply circuit 4 and connected to supply the charged power to the selection unit 5. With such a configuration, when the switch 50 is turned off (when power to the terminal 3A is stopped), the adapter 2A (1) keeps the selection unit 5 in the standby state by the power from the secondary battery 6. (2) When the supply of power to the terminal 3A starts, the start of the supply can be detected immediately, and (3) the power supplied to the terminal 3A is energized to the terminal 7A following the detection. The determination of whether to shut down or not can be processed quickly. However, since the function of this embodiment is achieved without the secondary battery 6, the secondary battery 6 is not an essential component for the present invention.

  Below, the outline | summary of the action | operation of the illumination set 1 is demonstrated first, and the function of adapter 2A, 2B for implement | achieving the said action | operation is demonstrated after that.

  At a certain timing, the user turns the switch 50 from open (OFF) to closed (ON). Then, power is supplied from the power supply terminals 20A and 20B to the terminals 3A and 3B. In this case, the power is supplied to the projector 100 and the lighting device 200 by the adapters 2A and 2B. As a result, the projector 100 starts projecting image light or illumination light, and the illumination device 200 starts to light.

  Thereafter, the user turns the switch 50 from closed (ON) to open (OFF). Then, the projector 100 stops projecting and the lighting device 200 is turned off.

  Thereafter, the user turns the switch 50 from open (OFF) to closed (ON). Then, power is supplied from the power supply terminals 20A and 20B to the terminals 3A and 3B. However, in this case, the power is not supplied to the projector 100 by the adapter 2A, but is supplied to the lighting device 200 by the adapter 2B. As a result, the projector 100 remains stopped while the lighting device 200 is turned on.

  Thereafter, the user turns the switch 50 from closed (ON) to open (OFF). Then, the lighting device 200 is turned off.

  Thereafter, the user turns the switch 50 from open (OFF) to closed (ON). Then, power is supplied from the power supply terminals 20A and 20B to the terminals 3A and 3B. However, in this case, the power is supplied to the projector 100 by the adapter 2A, but is not supplied to the lighting device 200 by the adapter 2B. As a result, the projector 100 starts projecting image light or illumination light, while the illumination device 200 remains off.

  Thereafter, the user turns the switch 50 from closed (ON) to open (OFF). Then, the projector 100 stops projecting.

  Thereafter, the user turns the switch 50 from open (OFF) to closed (ON). Then, power is supplied from the power supply terminals 20A and 20B to the terminals 3A and 3B. In this case, the power is supplied to the projector 100 and the lighting device 200 by the adapters 2A and 2B. Thereby, again, the projector 100 starts projecting image light or illumination light, and the illumination device 200 starts to light.

  The operations described above can be summarized as follows, focusing on the functions of the adapters 2A and 2B.

  In the adapter 2A, every time power is started to be supplied to the terminal 3A, either energization or interruption of power between the terminal 3A and the terminal 7A is sequentially selected according to the rule (energization → interruption → energization). The Moreover, this rule is cyclic, and the unit of the rule (energization → cutoff → energization) is repeated.

  In the adapter 2B, every time power is started to be supplied to the terminal 3B, either energization or interruption of power between the terminal 3B and the terminal 7B is sequentially selected according to the rule (energization → energization → interruption). The Moreover, this rule is cyclic, and the unit of the rule (energization → energization → cutoff) is repeated.

  The function of the adapter 2A will be described in more detail with reference to FIG.

  As shown in FIG. 3, the switch 50 is closed (ON) at a certain timing. Then, power is supplied from the power supply terminal 20A to the terminal 3A (S1). In response to the supply of power to the terminal 3A, the control unit 8 in the standby state is activated. Then, the control unit 8 reads the value of N stored in the nonvolatile memory in the storage unit 9, and increments the read value of N (adds “1” to the original value) (S2). Here, “N” is a natural number type variable, but the type of the variable is not limited to this. Next, the control unit 8 determines whether or not the value of N is “1” (S3). When the value of N is “1” (S3: YES), the control unit 8 controls the supply circuit 4 so that the terminals 3A and 7A are energized (S4). Then, the control unit 8 waits for the switch 50 to be turned off (S9). Note that the value of N incremented in step S2 is stored in the non-volatile memory in the storage unit 9.

  In step S3, when the value of N is not “1” (S3: NO), the control unit 8 determines whether or not the value of N is “2” (S5). When the value of N is “2” (S5: YES), the control unit 8 controls the supply circuit 4 so that the terminal 3A and the terminal 7A are not energized (SA6). That is, the power supplied to the terminal 3 </ b> A is interrupted by the supply circuit 4. Then, the control unit 8 waits for the switch 50 to be turned off (S9).

  In steps S3 and S5, when N is neither “1” nor “2” (S3: NO and S5: NO), the control unit 8 sets the value of N to “0” (S7). In addition, the control unit 8 controls the supply circuit 4 so that a current flows between the terminals 3A and 7A (SA8). Then, the control unit 8 waits for the switch 50 to be turned off (S9). Note that the value of N that is “0” in step S7 is stored in the nonvolatile memory in the storage unit 9.

  The function of the adapter 2B will be described in more detail with reference to FIG.

  As shown in FIG. 4, when step S3 is YES, the flow from step S1 through step S4 to step S9 is the same as the corresponding flow in adapter 2A. In FIG. 4, the same steps as those in FIG. 3 are denoted by the same reference numerals as those in FIG.

  In step S3, when the value of N is not “1” (S3: NO), the control unit 8 determines whether or not the value of N is “2” (S5). When the value of N is “2” (S5: YES), the control unit 8 controls the supply circuit 4 so that the terminal 3B and the terminal 7B are energized (SB6). Then, the control unit 8 waits for the switch 50 to be turned off (S9).

  In Steps S3 and S5, when the value of N is neither “1” nor “2” (S3 is NO and S5 is NO), the control unit 8 sets the value of N to “0” (S7). In addition, the control unit 8 controls the supply circuit 4 so that the terminal 3A and the terminal 7A are not energized (SB8). That is, the power supplied to the terminal 3B is cut off by the supply circuit 4. Then, the control unit 8 waits for the switch 50 to be turned off (S9). Note that the value of N that is “0” in step S7 is stored in the nonvolatile memory in the storage unit 9.

  With the configuration described above, each time power is started to be supplied to the terminal 3A of the adapter 2A, one of energization and interruption of power to the projector 100 is cyclically selected according to the rule (energization → interruption → energization). The On the other hand, whenever power is started to be supplied to the terminal 3B of the adapter 2B, one of energization and interruption of power to the lighting device 200 is cyclically selected according to the rule of (energization → energization → interruption).

  As a result, when the switch 50 is turned on at a certain point, power is supplied to both the projector 100 and the lighting device 200. Thereafter, when the switch 50 is turned off and then turned on, power is not supplied to the projector 100, but power is supplied to the lighting device 200. Thereafter, when the switch 50 is turned off and then turned on, power is supplied to the projector 100, but power is not supplied to the lighting device 200. Thereafter, when the switch 50 is turned off and then turned on, power is supplied to both the projector 100 and the lighting device 200.

  Therefore, the projector 100 and the lighting device 200 can be turned on and off separately by opening and closing one common switch 50.

(Embodiment 2)
According to the present embodiment, the configuration of the adapter 2A and the functions realized by the configuration are built in the projector 100 ′. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  5 includes a power receiving terminal 101, a supply circuit 104, a selection unit 105, a secondary battery 106, a power supply unit 107, a light source unit 110, an irradiation optical system 111, and a spatial light modulation device 112. And a projection optical system 113. The power supplied to the power supply unit 107 is supplied to the power receiving terminal 101 through the supply circuit 104. The power supply unit 107 supplies the power supplied from the supply circuit 104 to each unit including the light source unit 110 and the spatial light modulator 112. Note that the light source unit 110 of the present embodiment includes a light source and a drive circuit that drives the light source. The light source provided in the light source unit 110 is an LED (light emitting diode) light source.

  The selection unit 105 includes a control unit 108 and a storage unit 109, and functions by power supplied through the supply circuit 104. The storage unit 109 has the same function as the function of the storage unit 9 of the first embodiment.

  Each time the power starts to be supplied to the power receiving terminal 101, the selection unit 105 performs either one of energization and interruption of power between the power reception terminal 101 and the power supply unit 107 in accordance with the rule (energization → interruption → energization). Select cyclically. Similar to the first embodiment, this rule is cyclic, and the unit of the rule (energization → cutoff → energization) is repeated. When the selection unit 105 selects energization, the supply circuit 104 supplies power to the power supply unit 107, and when the selection unit 105 selects cutoff, the supply circuit 104 does not supply power to the power supply unit 107. It becomes.

  When the power supply unit 107 receives power from the supply circuit 104, the projector 100 'is turned on. Here, throughout this specification, “projector” is “ON” or “ON state” means that the power supply unit 107 supplies power to the light source unit 110, and as a result, light is emitted from the light source unit 110. And the case where the power supply unit 107 sets the projector 100 ′ to the standby state. The standby state of the projector 100 ′ may be a state in which the projector 100 ′ waits for a start command from a remote controller (not shown) outside the projector 100 ′, or is attached to the housing surface of the projector 100 ′. It may be a state of waiting for an activation command from a button (not shown). During the standby state, the power supply unit 107 supplies power necessary for waiting for an activation command to each unit of the projector 100 ′. During the standby state, the light source in the light source unit 110 is not turned on. When a start command is input during the standby state, the power supply unit 107 supplies power to the light source unit 110. Then, when the drive circuit drives the light source, the light source is turned on, and as a result, light is emitted from the light source unit 110.

  When light is emitted from the light source unit 110, the emitted light is incident on the spatial light modulation device 112 via the irradiation optical system 111, and is modulated by the spatial light modulation device 112 based on the image signal. The light (image light) modulated by the spatial light modulator 112 is projected outside by the projection optical system 113 and displayed as an image. The projector 100 may project illumination light using light from the light source unit 110. In this case, the spatial light modulator 112 may simply transmit the light from the light source unit 110 uniformly.

  With the above configuration, in this embodiment, even without the adapter 2A of the first embodiment, the projector 100 ′ and the lighting device 200 can be turned on and off by opening and closing one common switch 50, as in the first embodiment. However, it can be realized separately.

  The power supply unit 107 may be defined as a “power supply circuit”, a part for realizing the function of the supply circuit 104, a part for realizing the function of the selection unit 105, and a part for realizing the function of the power supply unit 107. A configuration including the above may be defined as a “power supply circuit”.

(Embodiment 3)
When the power receiving terminal 101 of the projector 100 is directly connected to the power feeding terminal 20A by omitting the adapter 2A of the first embodiment, the projector 100 is always turned on and the switch 50 is turned off when the switch 50 is turned on. The projector 100 is always turned off. In such an arrangement, whenever power is started to be supplied to the terminal 3B of the adapter 2B, either one of energization and interruption of the electric power to the lighting device 200 is cyclically repeated according to the rule of (energization → interruption). Thus, the adapter 2B may be configured.

  The function of the adapter 2B will be described with reference to FIG.

  As shown in FIG. 6, when step S3 is YES, the flow from step S1 through step S4 to step S9 is the same as the corresponding flow in the adapter 2A described with reference to FIG. In FIG. 6, the same steps as those in FIG. 3 are denoted by the same reference numerals as those in FIG.

  As shown in FIG. 6, when the value of N is not “1” in step S3 (S3: NO), the control unit 8 sets the value of N to “0” (SC5). In addition, the control unit 8 controls the supply circuit 4 so that the terminal 3B and the terminal 7B are not energized (SC6). That is, the power supplied to the terminal 3B is cut off by the supply circuit 4. Then, the control unit 8 waits for the switch 50 to be turned off (S9). The value of N set to “0” is stored in the nonvolatile memory in the storage unit 9.

  According to the first to third embodiments, the lighting device 200 and the projectors 100 and 100 ′ are electrically connected to the power source 60 through the common switch 50 by the adapters 2A and 2B and the projector 100 ′. Even if the switch 50 is opened and closed, an ON / OFF pattern in which one is turned on and the other is turned off can be realized.

(Modification 1)
In the first embodiment, a mode in which the projector 100 and the lighting device 200 are mixed has been described as an example. For example, if the adapter 2A is attached to some of the projectors 100 and the adapter 2B is attached to the other projectors 100, only some of the projectors 100 can be turned on. Similarly, if the adapter 2A is attached to some of the lighting devices 200 and the adapter 2B is attached to the other lighting devices 200, only some of the lighting devices 200 can be turned on. It becomes possible.

(Modification 2)
In the first embodiment, the two rules of the rule that the projector 100 follows and the rule that the lighting device 200 follows are combined, but three or more rules may be combined.

(Modification 3)
It is desirable that the order (rules) of energization and shutoff can be changed (selected) by hardware or software. Further, when the power source 60 is a DC power source, the adapters 2A and 2B and the projectors 100 and 100 ′ may be modified so as to exhibit the functions of the above-described embodiments while supporting DC power.

  DESCRIPTION OF SYMBOLS 1 ... Lighting set, 2A, 2B ... Adapter, 3A, 3B ... Terminal, 4 ... Supply circuit, 5 ... Selection part, 6 ... Secondary battery, 7A, 7B ... Terminal, 8 ... Control part, 9 ... Memory | storage part, 20A 20B ... Power supply terminal, 40 ... Power line, 50 ... Switch, 60 ... Power source, 100 ... Projector, 100 '... Projector, 101 ... Power receiving terminal, 104 ... Supply circuit, 105 ... Selection unit, 106 ... Secondary battery, 107 ... Power supply unit 108... Control unit 109 109 Storage unit 110 Light source unit 111 Irradiation optical system 112 Spatial light modulation device 113 Projection optical system 200 Lighting device

Claims (7)

A first terminal to which power is supplied from the outside;
A second terminal electrically connected to the power receiving terminal of the lighting device or projector;
A selector that selects one of energization and shutoff according to a cyclic rule each time the electric power starts to be supplied to the first terminal;
A supply circuit that supplies the power to the second terminal when the energization is selected by the selection unit, and does not supply the power to the second terminal when the cutoff is selected by the selection unit; ,
With an adapter. A projector,
A power receiving terminal to which power is supplied from the outside;
A power supply,
A selector that selects either energization or shutoff according to a cyclic rule each time the power starts to be supplied to the power receiving terminal;
A supply circuit that supplies the power to the power supply unit when the selection unit selects the energization, and does not supply the power to the power supply unit when the selection unit selects the cutoff;
With
When the power supply unit receives the power supply, the projector is turned on.
projector. The projector according to claim 2,
A light source unit;
The ON state is a state in which the light source unit emits light.
projector. The projector according to claim 2,
The ON state is a standby state.
projector. A method for controlling a projector having a power receiving terminal to which power is supplied from the outside,
A selection step of selecting either energization or shutoff according to a cyclic rule each time power is started to be supplied to the power receiving terminal;
When the energization is selected in the selection step, the projector is turned on, and when the blocking is selected in the selection step, the projector is not turned on.
Control method for a projector equipped with A projector control method according to claim 5, comprising:
The projector further includes a light source unit,
The ON state is a state in which the light source unit emits light.
Projector control method. The projector according to claim 5, wherein
The ON state is a standby state of the projector.
Projector control method.

Images