JP5786541B2 - Light source control device - Google Patents

Description

  The present invention relates to a light source control device for controlling a plurality of light sources provided in a gaming machine.

  In order to enhance the interest of the player, a device such as a spinning machine or a ball game machine has been devised to produce an effect that appeals to the player's visual, auditory, or senses. In particular, in order to produce an effect that appeals to the player's vision, a gaming machine may be provided with a large number of light sources. Further, for example, light emitting diodes (LEDs) are used as these light sources. And by using red, blue and green LEDs in combination, there is an effect that the emission color is changed variously.

  In order to enhance the production effect, hundreds of LEDs may be arranged on the front of the gaming machine. Then, the light emission brightness or the light emission period of each LED is adjusted according to the effect, so that the light emission state on the front surface of the gaming machine can be changed in various ways.

However, as the number of LEDs mounted on the gaming machine increases, the amount of wiring for driving the LEDs also increases, and a signal for controlling the LEDs provided in the processor unit for production is output. The number of terminals also increases. When the amount of wiring increases, it becomes difficult to install the wiring on the back of the gaming machine, and the cost of the effect processor unit increases.
Therefore, in order to reduce the amount of wiring and the number of terminals of the processor unit for production, a light source control device that is installed between the processor unit for production and each LED and controls the light emission intensity and light emission timing of the LED May be mounted on the machine.

For example, Patent Document 1 discloses an LED control in which a serial / parallel conversion circuit receives a serial data signal and an LED control clock from a CPU of a host device, converts them into LED light emission signals of parallel data signals, and emits a plurality of LEDs. An apparatus is disclosed.
Patent Document 2 discloses a driving system for a light emitter having a driver IC. The driver IC has a serial data line and a clock data line connected in cascade from a controller, and a serial signal from each controller. And a conversion circuit for converting the parallel signal and a drive circuit for operating the light emitter.

Japanese Utility Model Publication No. 4-96789 JP 2006-218137 A

In the technique disclosed in Patent Document 1 or 2, each LED is driven by a static lighting method in which a voltage is always applied during lighting. In the static lighting method, power consumption increases, so the number of LEDs that can be driven by the LED control device is limited to about 30 at the maximum.
However, as mentioned above, there are cases where hundreds of LEDs are mounted on a gaming machine, so in order to control all the LEDs, 10 or more light source control devices may be required. there were. If a large number of light source control devices are used in this way, the cost of the entire gaming machine increases. In addition, the arithmetic processor unit has to control a large number of light source control devices, and there is a problem that the control load of the processor unit is large.

  Therefore, an object of the present invention is to provide a light source control apparatus that can control more light sources.

  As one embodiment of the present invention, a light source control device that controls a plurality of light sources provided in a gaming machine is provided. The anodes of the plurality of light sources controlled by the light source control device are connected to any one of the plurality of first signal lines, and the cathode is connected to any one of the plurality of second signal lines, and is connected to the first signal line. The signal line and the second signal line are different for each light source. The light source control apparatus includes gradation data that defines a light emission amount of one of a plurality of light sources by a plurality of bits for each of the plurality of light sources, and an interface unit that receives a control command that is serially transmitted, For each of the plurality of first signal lines, a first period for setting a first period in which a light source connected to the first signal line among the plurality of light sources can be energized alternately at a constant period is set. To the first signal line connected to the anode of the light source connected to the second signal line of the plurality of light sources, for each of the plurality of second signal lines. On the other hand, while the first period is set, a second period in which the light source can be energized is set according to the light emission amount represented in the gradation data corresponding to the light source included in the control command. Command to generate a second signal to perform A voltage is applied to each of the analyzing unit and each of the plurality of first signal lines so that the potential of the first period set in the first signal is higher than the potential other than the first period. For each of the dynamic control unit and the plurality of second signal lines, a light source connected to the second signal line among the plurality of light sources during the second period set in the second signal. And a gradation control unit that enables energization.

  In this light source control device, the control command includes gradation control data that defines the number of bits representing the gradation data, and the command analysis unit uses a bit defined in the gradation control data as a storage part of the gradation data of the control command. It is preferable to extract gradation data for each of a plurality of light sources by dividing them with numbers.

  In addition, each of the plurality of first signal lines is connected to the discharge signal line, and the gradation control unit is configured so that each time the first period is set to any of the plurality of first signal lines, From the rise of the first period, it is possible to energize the plurality of first signal lines and the discharge signal line for a period shorter than the first period, and to discharge residual charges on the plurality of first signal lines. preferable.

  Furthermore, the light source control device receives a brightness adjustment signal representing a ratio of the plurality of light sources to the maximum light emission intensity, and thereby reduces a light emission intensity of each of the plurality of light sources according to the ratio represented by the brightness adjustment signal. It is preferable to have.

  The light source control device according to the present invention has an effect that more light sources can be controlled.

It is a wiring diagram of each LED driven by the light source control apparatus which concerns on one Embodiment of this invention. It is a schematic block diagram of the light source control apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the format of a control command. 2 is a timing chart showing an example of a time change of a voltage applied to each signal line shown in FIG. 1. It is a figure which shows the time change of the voltage of the signal wire | line relevant to LED when LED turns on erroneously. FIG. 6 is a timing chart showing another example of a temporal change in voltage applied to each signal line shown in FIG. 1. It is a schematic block diagram of the light source control apparatus by a modification. 1 is a schematic perspective view of a ball game machine including a light source control device according to one embodiment of the present invention. 1 is a schematic rear view of a ball game machine including a light source control device according to one embodiment of the present invention.

  Hereinafter, a light source control device according to an embodiment of the present invention will be described with reference to the drawings. Conventionally, in gaming machines, there are cases in which a large number of LEDs provided in the gaming machine are caused to emit light with the maximum light emission intensity, or are turned off to enhance the player's interest. For this reason, dynamic control in which the maximum light emission intensity of the LED is lower than that of static control has not been used so far in the LED for a game machine. In particular, dynamic control has not been employed in a light source control apparatus that controls a plurality of light sources. However, the inventor has found that even if dynamic control is applied to a light source control device that controls a plurality of light sources, the player's interest is not impaired. The present invention has been made based on such knowledge.

  This light source control device dynamically controls a plurality of LEDs wired in a matrix and adjusts the light emission amount of each LED by a pulse width modulation (PWM) method. For this purpose, this light source control device includes gradation data that specifies the gradation level for each LED or LED set from the host control device, receives a control command that is serially transmitted, analyzes the control command, A voltage signal corresponding to the command is output in parallel to each of the signal line connected to the anode side and the signal line connected to the cathode side of each LED.

FIG. 1 is a wiring diagram of each LED driven by a light source control device according to one embodiment of the present invention. In this example, the LEDs 10-1 to 10-16 that are light sources are connected in a 4 × 4 matrix. The anodes of the LEDs 10-1 to 10-4 are connected to the signal line COM1. Similarly, the anodes of the LEDs 10-5 to 10-8 are connected to the signal line COM2. The anodes of the LEDs 10-9 to 10-12 are connected to the signal line COM3. The anodes of the LEDs 10-13 to 10-16 are connected to the signal line COM4. Further, each of the signal lines COM1 to COM4 is connected to a discharge signal line DISC.
Further, the cathodes of the LEDs 10-1, 10-5, 10-9, and 10-13 are connected to a signal line SEGA. Similarly, the cathodes of the LEDs 10-2, 10-6, 10-10, and 10-14 are connected to the signal line SEGB. Furthermore, the cathodes of the LEDs 10-3, 10-7, 10-11, and 10-15 are connected to the signal line SEGC. The cathodes of the LEDs 10-4, 10-8, 10-12, and 10-16 are connected to the signal line SEGD.
Each of the signal lines COM1 to COM4, SEGA to SEGD, and DISC is connected to a light source control device according to one embodiment of the present invention described later.

Each of the LEDs 10-1 to 10-16 has a voltage applied to the signal line so that the potential of the signal line connected to the cathode is lower than the potential of the signal line connected to the anode of the LED. The LED is energized and lights up. On the other hand, if the potential of the signal line to which the anode of the LED is connected is equal to the potential of the signal line to which the cathode is connected, or if the potential of the signal line to which the cathode is connected back is higher, the LED is not energized. ,not light.
Therefore, the light source control device can light any LED of the LEDs 10-1 to 10-16 by adjusting the potentials of the signal lines COM1 to COM4 and SEGA to SEGD.

Each of the LEDs 10-1 to 10-16 may include a plurality of LEDs connected in series or in parallel. Further, the actual arrangement of the LEDs 10-1 to 10-16 does not have to be in a matrix form, but for the production, such as the shape of the game board on which the LEDs are arranged, or an accessory part provided on the game board. It is determined by the positional relationship with the member. Furthermore, the number of signal lines COMy connected to the anode of the LED may not be four. However, as will be described later, a pulse signal is applied to the signal line COMy alternately at a predetermined cycle one by one, having a high potential only for a predetermined period and enabling energization of the LED connected to that signal line. Is done. Therefore, if the number of signal lines COMy is too large, the period during which the LEDs can be lit within a predetermined period is shortened. As a result, the maximum light emission intensity of each LED is lowered, and the player feels dark. Therefore, the number of signal lines COMy is preferably 8 or less.
Also, the number of signal lines SEGx connected to the cathode of the LED need not be four.

FIG. 2 is a schematic configuration diagram of a light source control device according to one embodiment of the present invention. As shown in FIG. 2, the light source control device 1 includes an interface circuit 2, a command analysis circuit 3, a register 4, a setting circuit 5, a dynamic control circuit 6, and a gradation control circuit 7.
Each of these units included in the light source control device 1 may be mounted on a circuit board (not shown) as a separate circuit, or may be mounted on the circuit board as an integrated circuit in which these units are integrated. May be.

The interface circuit 2 is, for example, an interface circuit for connecting a light source control device 1 and a processor unit (not shown; hereinafter simply referred to as a production CPU) for rendering a gaming machine in which the light source control device 1 is mounted. It is. The interface circuit 2 receives a control command having a plurality of bits transmitted serially from the effect CPU and a clock signal for synchronizing with each of the plurality of bits included in the control command in order to analyze the control command. And receive. The clock signal can be, for example, a signal having a rectangular pulse for every predetermined number of bits in the control command.
Further, the interface circuit 2 receives an identification signal for specifying the light source control device to be controlled by the control command from the effect CPU. The interface circuit 2 passes the control command, clock signal, and identification signal to the command analysis circuit 3.
The interface circuit 2 transfers the received control command and clock signal to another light source control device in the next stage when a plurality of light source control devices 1 are cascade-connected.
Details of the control command will be described later.

  The command analysis circuit 3 has at least one processor and its peripheral circuits. Then, the command analysis circuit 3 refers to the clock signal, extracts a bit string included in the control command, and analyzes the bit string in accordance with the format of the control command, thereby specifying the light emission amount of each LED.

  FIG. 3 is a diagram illustrating an example of the format of the control command. The control command 300 includes a START flag 301, a device address 302, control data 303, a plurality of gradation data 304, and an END flag 305 in order from the top. Further, the control command 300 may include a 1-bit spacer having a value of, for example, “0” between adjacent flags, addresses, and data.

The START flag 301 is a bit string indicating the head of the control command 300, and in this embodiment, is a bit string in which nine bits having a value of “1” are continuous. The START flag 301 may be a bit string that does not match any other bit string in the control command 300.
The device address 302 is identification information for specifying the light source control device to be controlled by the control command 300, and is represented by a 7-bit bit string in this embodiment. As described above, the command analysis circuit 3 determines whether or not the device address 302 matches the identification signal ADR. If the device address 302 matches, the light source control device 1 is determined to be a control target of the control command 300. .

The control data 303 includes a 1-bit gradation control bit 3031 that defines the bit length of each gradation data 304 that represents the light emission intensity of each LED controlled by the light source control device 1, and a head address of a register in which each gradation data is stored. And a register address 3032 that defines If the gradation control bit 3031 is '0', each gradation data 304 is represented by 8 bits, whereas if the gradation control bit 3031 is '1', each gradation data 304 is represented by 4 bits. Is done. By setting a large number of bits of gradation data, the emission intensity of each LED can be set in detail. On the other hand, by setting the number of bits of the gradation data to be small, the control command is shortened and the time required for transferring the control command is shortened, so that the light emission intensity of each LED can be switched in a short cycle. In addition, the load on the CPU for rendering is reduced by shortening the control command.
The control data 303 may further include the number of gradation data that defines the number of gradation data 304 included in the control command. Thereby, when the number of LEDs smaller than the maximum number of LEDs that can be controlled simultaneously by the light source control device 1 is connected to the light source control device 1, the control command can be shortened.

  Each of the plurality of gradation data 304 represents the light emission intensity of the LED connected to the light source control device 1. When the gradation data 304 is represented by 4 bits, the gradation data 304 takes values from “0” to “15”, and thus the emission intensity of each LED is represented in 16 levels. On the other hand, when the gradation data 304 is represented by 8 bits, the gradation data 304 takes values from “0” to “255”, and thus the emission intensity of each LED is represented in 256 levels. The larger the value of the gradation data 304, the higher the emission intensity of the corresponding LED. For example, in the case where the gradation data 304 is represented by 4 bits, if the value of the gradation data 304 is “15” (that is, all bits are “1”), the light emission intensity of the corresponding LED is also maximum. On the other hand, if the value of the gradation data 304 is “7”, the light emission intensity of the corresponding LED is ½ of the maximum intensity, and if the value of the gradation data 304 is “0”. The corresponding LED is turned off. Similarly, when the gradation data 304 is represented by 8 bits, if the value of the gradation data 304 is “255” (that is, all bits are “1”), the emission intensity of the corresponding LED is also determined. On the other hand, if the value of the gradation data 304 is “0”, the corresponding LED is turned off.

The order from the top of each gradation data 304 corresponds to the position on the wiring of the LED connected to the light source control device 1. For example, the LED corresponding to each gradation data 304 is specified according to the raster scan order. For example, the light source control device 1 can control a maximum of 96 LEDs, and each LED is one of 8 signal lines COMy (y = 1 to 8) and 12 signal lines SEGx (x = 1 to 12). It is assumed that it is connected to any of the above. In this case, the i-th (i = 0 to 95) gradation data 304 from the top corresponds to the LED connected to the signal line COM (i / 12 + 1) and the signal line SEG (i% 12 + 1). To do. The operator% is a remainder operator.
The order from the top of each gradation data 304 may correspond to the arrangement of other LEDs.

  The END flag 305 is a bit string indicating the end of the control command 300. The END flag 305 may be a bit string that does not match the START flag and other data bit strings included in the control command.

When receiving the control command, the command analysis circuit 3 detects, for example, a bit string that matches a template having the same bit string as the START flag in the control command, and sets the bit string as the START flag. Then, the command analysis circuit 3 extracts a device address from the control command according to the format of the control command.
If the device address does not match the identification information ADR, the command analysis circuit 3 discards the control command. On the other hand, if the device address matches the identification information ADR, the command analysis circuit 3 extracts control data from the control command according to the format of the control command, refers to the gradation control bits included in the control data, and determines each level. Check the bit length of the key data. Then, the command analysis circuit 3 extracts each gradation data by dividing the portion of the control command in which the gradation data is stored by the number of bits defined by the gradation control bits, and the gradation data is stored in the register 4. Remember me.

  Further, the command analysis circuit 3 generates a signal representing a voltage applied to each signal line COMy and SEGx according to each gradation data.

  In the present embodiment, the light source control device 1 dynamically controls each LED and sets the light emission intensity of each LED according to the PWM method. Specifically, the light source control device 1 has a high potential at which the LED connected to the signal line can be turned on in order for each signal line COMy in order for a certain period (for example, 1 msec). A periodic pulse signal that is a low potential that does not light up is output. On the other hand, for each signal line SEGx, the light source control device 1 corresponds to the LED during a period in which a pulse is applied to the signal line COMy in which the anode of the LED in which the cathode is connected to the signal line is connected. A pulse signal is output that has a low potential only during a period corresponding to the light emission intensity represented by the gradation data, and a high potential during the other periods.

FIG. 4 is a timing chart showing an example of a time change of the voltage applied to each signal line shown in FIG.
In FIG. 4, waveforms 401 to 404 represent signal waveforms applied to the signal lines COM1 to COM4, respectively, and waveforms 405 to 408 represent signal waveforms applied to the signal lines SEGA to SEGD, respectively. The horizontal axis for each signal waveform represents time. The vertical axis represents the potential applied to the signal line, H represents a high potential, and L represents a low potential.
As shown in the signal waveforms 401 to 404, for each of the signal lines COM1 to COM4, pulses having a high potential are alternately applied to only one of the signal lines in order from COM1 to COM4. The pulse width is 1 msec, for example. Therefore, in this case, a pulse is applied once to each of the signal lines COM1 to COM4 with 4 msec as one period.

On the other hand, as shown in the signal waveforms 405 to 408, for each of the signal lines SEGA to SEGD, during the period when the high potential pulse is applied to the signal line COMy (y = 1, 2, 3, 4), By the PWM control, the potential becomes low for a period corresponding to the light emission intensity of the LED connected to the signal line COMy and the signal lines SEGA to SEGD. For example, in the period P1 in which a pulse is applied to the signal line COM1, the signal line SEGA is at a low potential for a quarter of the period P1. Therefore, the light emission intensity of the LED 10-1 connected to the signal lines COM1 and SEGA is 1/4 of the maximum light emission intensity. Similarly, in the period P1, the signal lines SEGB and SEGC are at the same potential as the period P1, respectively, and are at a low potential by 1/2 of the period P1. Therefore, the emission intensity of the signal line COM1 and is connected to SEGB LED10- 2 becomes maximum emission intensity, the emission intensity of which is connected to the signal line COM1 and SEGC LED10- 3 is 1/2 of the maximum signal strength . Further, during the period P1, the signal line SEGD is always at a high potential. Therefore, it is connected to the signal line COM1 and SEGD LED10- 4 does not emit light.

  Note that immediately after the period in which the pulse is applied to the signal line COMy, a time lag occurs until all the charges accumulated in the signal line are discharged. While the charge remains in the signal line, the LED connected to the signal line may be erroneously lit.

The principle of erroneous lighting due to residual charges will be described with reference to FIG. In FIG. 5, the horizontal axis represents time. Waveform 500 represents the potential at point P in FIG. Waveforms 501 and 502 represent waveforms of signals applied to the signal lines COM1 and COM2, respectively. A waveform 503 represents a waveform of a signal applied to the signal line SEGA.
As shown in the waveform 501, 502, period applied pulse is applied to the signal line COM1 is completed at time t _1, while the pulse is applied to start the signal line COM2. However, as shown in the waveform 500, the point P, the residual charge, even after time t _1, the potential does not decrease immediately, gradually decreases as the residual charge is released. Here, if the potential of the signal line SEGA is lowered immediately after time t ₁ to turn on the LED 10-5 connected to the signal line COM 2 and SEGA, the voltage between the potential of the signal line COM 1 and the signal line SEGA becomes LED 10. −1 becomes larger than the minimum voltage to be lit, and as a result, the LED 10-1 is also lit erroneously during a period from immediately after time t ₁ until the residual charge of the signal line COM1 is sufficiently discharged.

  Therefore, the light source control device 1 discharges the residual charges of the signal lines COMy by allowing the signal lines and the discharge signal line DISC to be energized only during a predetermined discharge period immediately after the signal line to which the pulse is applied is switched. After that, by lowering the potential of each signal line SEGx, it is possible to prevent erroneous lighting of the LED.

FIG. 6 is a timing chart showing another example of the change over time of the voltage applied to each signal line shown in FIG.
In FIG. 6, waveforms 601 to 604 represent signal waveforms applied to the signal lines COM1 to COM4, respectively. A waveform 605 represents a time change between a period during which the discharge signal line DISC can be energized and a period during which the discharge signal line DISC cannot be energized. Waveforms 606 to 609 represent signal waveforms applied to the signal lines SEGA to SEGD, respectively. The horizontal axis for each of the signal waveforms 601 to 604 and 606 to 609 represents time. The vertical axis represents the potential applied to the signal line, H represents a high potential, and L represents a low potential. Furthermore, with respect to the waveform 605, the horizontal axis represents time, the vertical axis “permitted” represents that energization is possible, and “no” represents that energization is not possible.

As shown in the signal waveform 605, the discharge signal line DISC is set to be energized simultaneously with the rise of each pulse applied to each signal line COM1 to COM4. During the predetermined discharge period, the discharge signal line DISC is kept energized. After the discharge period has elapsed, the potentials of the signal lines SEGA to SEGD connected to the LEDs to be lit are lowered.
Note that the discharge period is set to the minimum value of the period during which the residual charges on the signal line COMy are discharged to such an extent that the LED is not erroneously turned on, for example, 20 μsec.

In this embodiment, since the LED cannot be lit during the discharge period, the maximum light emission amount of the LED is reduced by the ratio of the discharge period to the time length of the pulse applied to the signal line COMy. However, since the discharge period is about several percent with respect to the time length of the pulse, the rate at which the maximum light emission amount decreases is only about several percent.
Further, a discharge setting flag indicating whether or not to set a discharge period may be included in the control data of the control command. In this case, the command analysis circuit 3 may switch whether or not to set the discharge period by referring to the value of the discharge setting flag. For example, if the discharge setting flag is set to a value (for example, '1') indicating that the discharge period is set, the command analysis circuit 3 applies to each signal line COMy as shown in FIG. A discharge period that starts at the same time as the rising edge of the pulse is set, and the discharge signal line DISC can be energized during the discharge period.
On the other hand, if the discharge setting flag is set to a value (for example, “0”) indicating that the discharge period is not set, the command analysis circuit 3 does not set the discharge period as shown in FIG. Next, the signal waveform for each signal line is determined.

For example, the command analysis circuit 3 sets, for each signal line COMy, a pulse in which an LED connected to the signal line can be energized alternately at a constant period, and a period in which the pulse is applied for each signal line COMy. A signal having a first potential and a second potential different from the first potential is generated for a period in which no pulse is applied. Then, the command analysis circuit 3 outputs a signal corresponding to each signal line COMy to the dynamic control circuit 6 in parallel via the setting circuit 5.
In addition, the command analysis circuit 3 applies, for each signal line SEGx, a period in which a pulse is applied to the signal line COMy to which the anode of the LED connected to the signal line among the LEDs 10-1 to 10-16 is connected. In addition, a period during which the LED can be energized is set according to the light emission amount represented in the gradation data corresponding to the LED included in the control command. The command analysis circuit 3 has a first potential during a period in which each of the signal lines SEGx and the discharge signal line DISC can be energized, and is different from the first potential for a period in which the energization is impossible. A signal having the second potential is generated. Then, the command analysis circuit 3 outputs a signal corresponding to each signal line SEGx and the discharge signal line DISC to the gradation control circuit 7 in parallel via the setting circuit 5.

The register 4 includes, for example, a volatile semiconductor memory circuit that can be read and written. The register 4 stores gradation data of each LED included in the control command received by the light source control device 1. The register 4 receives the new control command from the command analysis circuit 3, and the level included in the previous control command until the gray level data included in the previous control command is rewritten with the gray level data included in the new control command. Holds key data.
Then, the command analysis circuit 3 identifies the light emission amount of each LED according to the gradation data stored in the register 4 until a new control command is received. Therefore, the light emission pattern of each LED controlled by the light source control device 1 is maintained as the light emission pattern defined in the previous control command until the light source control device 1 receives a new control command.

  The setting circuit 5 receives a setting signal for instructing a setting common to each signal line from the effect CPU, and adjusts a signal output from each signal line according to the setting signal. For example, the setting circuit 5 inverts the signal value output from the command analysis circuit 3 to the gradation control circuit 7 when receiving the inversion signal INV that is one of the setting signals from the effect CPU. That is, during a period in which a signal having the first potential is output from the command analysis circuit 3 to a certain signal line SEGx, the gradation control circuit 7 cannot energize the LED connected to the signal line SEGx. On the other hand, during a period in which a signal having the second potential is output from the command analysis circuit 3, the gradation control circuit 7 can energize the LED connected to the signal line SEGx.

  The setting circuit 5 is another one of the setting signals from the effect CPU. When the luminance adjustment signal ADJ representing the ratio to the maximum light emission intensity of the LED is received, the setting circuit 5 pulses each signal line COMy according to the ratio. The period during which is applied is adjusted. For this purpose, the setting circuit 5 shortens the period during which a signal having the first potential is output to each signal line COMy from the command analysis circuit 3 to the dynamic control circuit 6 according to the ratio. Thereby, for example, when the gaming machine is in a standby state (that is, when there is no player playing with the gaming machine), the light emission pattern of each LED itself is a pattern according to the effect, The emission intensity of all LEDs can be reduced uniformly according to the ratio. Therefore, the light source control device 1 can reduce the control load of the effect CPU. Further, for example, when the gaming machine equipped with the light source control device 1 is in a standby state, the light source control device 1 uses the brightness adjustment signal ADJ to uniformly reduce the light emission intensity of all the LEDs. The power consumption of the gaming machine can be suppressed.

  The dynamic control circuit 6 is connected to each signal line COMy, and has a switching element (not shown) such as a transistor for each signal line. For example, for each signal line COMy, a signal for the signal line received from the command analysis circuit 3 is input to the switching element. Then, while the signal has the first potential, the switching element conducts the corresponding signal line COMy to a power source (not shown), while if the signal has the second potential, the corresponding signal line COMy. Do not connect line COMy to power. As a result, the dynamic control circuit 6 outputs a voltage signal having a waveform corresponding to the signal received from the command analysis circuit 3 to each signal line COMy.

  The gradation control circuit 7 is connected to each signal line SEGx and the discharge signal line DISC, and each signal line SEGx includes a switching element (not shown) such as a transistor. For example, for each signal line SEGx and discharge signal line DISC, the signal for the signal line received from the command analysis circuit 3 is input to the switching element. The switching element grounds the corresponding signal line SEGx or DISC while the signal has the first potential, while the corresponding signal line SEGx while the signal has the second potential. Or do not ground DISC. As a result, the gradation control circuit 7 can energize the signal lines SEGx and DISC only during the period specified by the signal received from the command analysis circuit 3.

  As described above, since this light source control device controls the lighting timing and light emission intensity of each LED by dynamic control using the PWM method, the power consumption of each LED can be suppressed. As a result, the light source control device can control a larger number of LEDs. Therefore, by using this light source control device, the number of light source control devices mounted on the gaming machine can be reduced.

In addition, this invention is not limited to said embodiment. For example, the light source controlled by the light source control device may not be an LED. The light source may be a light source whose emission intensity can be controlled by the PWM method.
The function of the setting circuit may be executed by a processor included in the command analysis circuit. In this case, the command analysis circuit corrects the signals to the signal lines COMy, SEGx, and DISC based on the setting signal received from the effect CPU, and then outputs them to the dynamic control circuit and the gradation control circuit.

  According to another modification, the light source control device may further include a constant current circuit for adjusting the amount of current flowing through each LED according to the ratio defined by the brightness adjustment signal ADJ. .

  FIG. 7 is a schematic configuration diagram of the light source control device 11 according to this modification. The light source control device 11 includes an interface circuit 2, a command analysis circuit 3, a register 4, a setting circuit 5, a dynamic control circuit 6, a gradation control circuit 7, and a constant current circuit 8. The light source control device 11 according to this modification is different from the light source control device 1 shown in FIG. 2 in that a constant current circuit 8 is provided. Therefore, the constant current circuit 8 and related parts will be described below.

The constant current circuit 8 includes, for example, a variable resistor connected between each signal line SEGx and the gradation control circuit 7. In this modification, when the setting circuit 5 receives the brightness adjustment signal ADJ, the setting circuit 5 sets the resistance value of each variable resistor included in the constant current circuit 8 instead of adjusting the period during which the pulse is applied to each signal line COMy. Then, the setting circuit 5 adjusts so that the light emission luminance of each LED is reduced by the ratio defined in the luminance adjustment signal ADJ received. Thereby, the light source control apparatus 11 can adjust the emitted light amount of each LED uniformly.
In still another modification, the constant current circuit 8 may include a variable resistor connected between each signal line COMy and the dynamic control circuit 6. Also in this case, the resistance value of each variable resistor is adjusted so that the light emission luminance of each LED is reduced by the ratio specified in the luminance adjustment signal ADJ received by the setting circuit 5, so that the light source control device The amount of light emitted from each LED can be adjusted uniformly.

Further, the light source control device according to the above-described embodiment or its modification may be mounted on a gaming machine such as a ball game machine or a spinning game machine.
FIG. 8 is a schematic perspective view of the ball game machine 100 including the light source control device according to the above-described embodiment or its modification. FIG. 9 is a schematic rear view of the ball game machine 100. As shown in FIG. 8, the ball game machine 100 is provided in a large area from the top to the center, and includes a game board 101 that is a main body of the game machine, and a ball receiving part that is disposed below the game board 101. 102, an operation unit 103 having a handle, a display device 104 provided substantially in the center of the game board 101, and a front surface of the game board 101, which is disposed around the display device 104 and below the game board 101. And an accessory part 105 used for production. A rail 106 is provided on the side of the game board 101. On the game board 101, a number of obstacle nails (not shown) and at least one winning device 107 are provided.

  The operation unit 103 launches a game ball with a predetermined force from a launching device (not shown) according to the amount of rotation of the handle by the player's operation. The launched game ball moves upward along the rail 106 and falls between a number of obstacle nails. When it is detected by a sensor (not shown) that a game ball has entered any winning device 107, the main control circuit 110 provided on the back of the game board 101 determines a predetermined value corresponding to the winning device 107 containing the game ball. The game balls are paid out to the ball receiving unit 102 via a ball payout device (not shown). Further, the main control circuit 110 displays various images on the display device 104 via the effect CPU 111 provided on the back of the game board 101.

In addition, a plurality of LEDs 108 are arranged in the accessory part 105, and each LED 108 is controlled by the light source control device 112 according to the embodiment of the present invention provided on the back of the game board 101. Note that the LEDs may be installed on the front surface of the game board 101 or around the game board 101 other than the accessory part 105.
Based on the state signal indicating the state of the game transmitted from the main control circuit 110 to the effect CPU 111, the effect CPU 111 determines the LED to be lit and the emission intensity of the LED to be lit among the LEDs 108, and follows the determination. Generate control commands. Then, the production CPU 111 outputs the generated control command to the light source control device 112. For example, before the game ball enters the winning device 107, the effect CPU 111 sets the gradation control bit included in the control data of the control command to “1”, and roughly sets the light emission intensity of each LED. On the other hand, when it is detected that the game ball has entered the winning device 107 and a state signal indicating this is input from the main control circuit 110 to the effect CPU 111, the effect CPU 111 sets the gradation control bit to “0”. Set the emission intensity of each LED in detail. Further, when the ball game machine 100 is in a standby state, the production CPU 111 generates a luminance adjustment signal ADJ for setting the luminance ratio to 50%, for example, so as to reduce the light emission luminance of each LED 108, and adjusts the luminance. The signal ADJ is output to the light source control device 112.
Then, the light source control device causes each LED to blink at a predetermined light emission intensity in accordance with the control command and the brightness adjustment signal ADJ.

  As described above, those skilled in the art can make various modifications in accordance with the embodiment to be implemented within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1, 11 Light source control apparatus 2 Interface circuit 3 Command analysis circuit 4 Register 5 Setting circuit 6 Dynamic control circuit 7 Gradation control circuit 8 Constant current circuit 10-1 to 10-16 LED
COM1 to COM4, SEGA to SEGD signal line 100 bullet ball game machine 101 game board 102 ball receiving unit 103 operation unit 104 display device 105 accessory unit 106 rail 107 winning device 108 decoration device 110 main control circuit 111 CPU for production
112 Light source control device

Claims (3)

A light source control device for controlling a plurality of light sources provided in a gaming machine, wherein each anode of the plurality of light sources is connected to one of a plurality of first signal lines, and a cathode is a plurality of second signal lines. And the set of the first signal line and the second signal line to be connected is different for each light source, and the light source control device includes:
An interface unit that includes gradation data that defines a light emission amount of one of the plurality of light sources by a plurality of bits for each of the plurality of light sources, and that receives a control command that is serially transmitted;
For each of the plurality of first signal lines, a first period in which a light source connected to the first signal line among the plurality of light sources can be energized is alternately set at a constant period. The first signal is generated, and the anode of the light source connected to the second signal line among the plurality of light sources is connected to each of the plurality of second signal lines. While the first period is set for one signal line, the light source can be energized according to the light emission amount represented in the gradation data corresponding to the light source included in the control command. A command analysis unit for generating a second signal for setting a second period,
Dynamic that applies a voltage to each of the plurality of first signal lines such that the potential of the first period set in the first signal is higher than the potential of other than the first period. A control unit;
For each of the plurality of second signal lines, a light source connected to the second signal line among the plurality of light sources is energized during the second period set in the second signal. A gradation control unit to enable;
I have a,
The control command includes gradation control data that defines the number of bits representing the gradation data,
The command analysis unit extracts the gradation data for each of the plurality of light sources by dividing the storage portion of the gradation data of the control command by the number of bits defined in the gradation control data. A light source control device characterized by the above. Each of the plurality of first signal lines is connected to a discharge signal line,
Each time the first period is set for any of the plurality of first signal lines, the gradation control unit has a period shorter than the first period from the rise of the first period, 2. The light source control device according to claim 1, wherein the plurality of first signal lines and the discharge signal line can be energized to discharge residual charges of the plurality of first signal lines. And a setting circuit configured to receive a luminance adjustment signal representing a ratio of the plurality of light sources to the maximum emission intensity, and to reduce the emission intensity of each of the plurality of light sources according to the ratio represented by the luminance adjustment signal. Item 3. The light source control device according to Item 1 or 2 .

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