JP2003190416A - Pachinko game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pachinko game machine for matching actual brightness obtained by the gradation control of LED with desired brightness by using the enabling terminal and the latch terminal of a digital IC circuit connected with the LED. <P>SOLUTION: By using the enabling terminal and the latch terminal of an input/output port connected with the multicolor LED, even when disconnecting the multicolor LED connected to the output terminal of the input/output port in a state where the enabling signal 61 of the enabling terminal of the input/ output port is 'H', a state where pulse current can flow through the multicolor LED is kept if the latch signal of the latch terminal of the input/output port is 'L'. Consequently, it is possible to cause the pulse current to flow through the multicolor LED based on most of 'time elements' constituting 'control unit time' by the gradation control of the multicolor LED. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pachinko machine for controlling a lighting mode of an LED, which is a light emitting source of a decorative article.

[0002]

2. Description of the Related Art For example, as shown in FIG. 10, a central electric decoration 103, a pair of electric pinwheels 104, and a pair of shoulder electric decorations 10 are provided on a game area 102 of a conventional pachinko machine 101.
5, an electric decoration such as the lower electric decoration 106 is provided.
Further, on the frame 108 above the game area 102, an electric ornament such as a frame electric ornament 109 is provided. In this respect, a lamp is usually used as a light emitting source for these electric decorations.

And, in the pachinko machine 101 of FIG. 10,
In order to control the lighting mode of such a lamp, it has a plurality of substrates as shown in the block diagram of FIG. That is, the main control CPU 12 is provided on the substrate 121 of FIG.
2, main control ROM 123, main control RAM
124, an input / output port 125, etc. are mounted. Then, the main control CPU 122 sends the variation pattern signal to the substrate 131 of FIG. 11 via the input / output port 125 based on the control method and other technical information stored in the main control ROM 123, the main control RAM 124 and the like. Have been sent to.

On the other hand, the substrate 131 of FIG. 11 has a lamp lighting control CPU 132 and a lamp lighting control ROM 13.
3, a lamp lighting control RAM 134, an input / output port 135, and the like are mounted. Furthermore, the input / output port 135 has a first lamp 141 and a second lamp 14
2, the third lamp 143, the fourth lamp 144, the fifth lamp 145, etc. are connected. In addition, these lamps
The central illumination 103, a pair of illuminated windmills 104, a pair of shoulder illuminations 105, a lower illumination 106, a frame illumination 109, and other illumination light sources.

Then, the lamp lighting control CPU 132
Is based on the control method and other technical information stored in the lamp lighting control ROM 133, the lamp lighting control RAM 134 and the like, based on the variation pattern signal received via the input / output port 135, the input / output port 135.
Connected to the first lamp 141, the second lamp 142,
Third lamp 143, fourth lamp 144, fifth lamp 14
The lighting modes such as 5 are controlled respectively.

In this regard, the lamp lighting control CPU 132
Controls the lighting modes of the first lamp 141, the second lamp 142, the third lamp 143, the fourth lamp 144, the fifth lamp 145, etc. by transmitting serial data to the input / output port 135. is doing.

Specifically, as shown in FIG. 12, the lamp lighting control CPU 132 first transmits the enable signal 151 to the input / output port 135 every 1 ms which is the cycle of the clock signal. Then, while the enable signal 151 is ON, the lamp lighting control C
The PU 132 transmits the serial data 152 to the input / output port 135. After that, in the input / output port 135, the serial data 152 is converted into parallel data, the enable signal 151 is turned off, and at the same time, the first lamp 14 is turned on the basis of the parallel data.
1 and the second lamp 142, the third lamp 143, etc., by passing an electric current, the first lamp 141, the second lamp 1
The lighting modes of the lamp 42, the third lamp 143, and the like are controlled.

In this regard, at the input / output port 135, the first lamp 141, the second lamp 142, the third lamp 143, etc. are disconnected from the circuit while the enable signal 151 is turned on, so that the clock is used. Based on the parallel data converted from the serial data 152 at every 1 ms which is the period of the signal, the first lamp 141 and the second lamp 141
An electric current can be passed through the lamp 142, the third lamp 143, and the like.

[0009]

On the other hand, in addition to the above-mentioned lamp, an LED can be considered as a light emitting source of the electric decoration. In this respect, the blinking operation of the LED is more diverse than that of the conventional lamp (quick light emission / extinction, increase / decrease of light amount, high density, etc.). Therefore, it is possible to use LE with the pachinko machine 101 of FIG.
When controlling the brightness of D, for example, 8-step gradation control as shown in FIG. 13 can be considered. That is, 1 ms, which is the cycle of the clock signal, is set as a "time element", and the "control unit time" is configured by the seven "time elements", and among the seven "time elements" of the "control unit time". , L
Depending on the number of "time elements" that flow a pulse current through the ED, L
Controls the brightness of the ED.

Therefore, as shown in FIG.
Among the seven “time elements” of the “control unit time”, when the pulse current is passed through the LED in all the “time elements”, it is LE
The brightness of D is the highest, and as shown in (g) of FIG. 13, one of the seven “time elements” of “control unit time” is 1
When a pulsed current is passed through the LED with each "time element",
The brightness of the LED becomes the smallest. In addition, the number of "time elements" that flow a pulse current through the LED is 6, 5, 4,
The brightness of the LED decreases as the number decreases to 3 and 2 ((b), (c), (d), (e),
(F)). As shown in (h) of FIG. 13, when the pulse current is not applied to the LED in all the "time elements" of the seven "time elements" of the "control unit time",
There is no brightness.

Then, as shown in FIG. 14, this gradation control is continuously performed for "control unit time" to obtain L
The lighting mode of the ED can be controlled. For example, in FIG.
In (α) of 4, the pulse current is applied to the LED in all of the seven “time elements” of each “control unit time”,
To the player, the LED appears to continue to illuminate in the brightest state. In addition, in (β) of FIG. 14, LE is used for all seven “time elements” of each “control unit time”.
No pulse current is applied to D, and from the player's perspective, L
The ED appears to stay off. Further, in (γ) of FIG. 14, as the “control unit time” progresses, L
The number of "time elements" for passing a pulse current through the ED is decreasing by one, and the LED seems to be gradually darker to the player. Further, in (δ) of FIG. 14, as the “control unit time” progresses, the number of “time elements” that pass the pulse current to the LED increases by one, and from the player's point of view, the LED is gradually turned on. It looks bright.

Therefore, as shown in FIG. 15, for example, for each of five adjacent LEDs, each "control unit time" is
If a pulsed current is applied to the seven "time elements" of each, the respective five LEDs adjacent to each other can be controlled so that each light emission trails. Such control is LE
It utilizes the agile flashing / extinction of the blinking operation of D, which cannot be realized with conventional lamps. Note that, in FIGS. 14 and 15, for convenience of description, each “time element” between the last “time element” of the “control unit time” and the first “time element” of the next “control unit time” is “time”. It is wider than between "elements", but is actually the same as between "time elements". Further, t, which is the "control unit time", is 7 (ms).

Of course, in the pachinko machine 101 of FIG. 10, as shown in FIG. 12, during transmission of serial data,
Since the enable signal 151 is turned on, as shown in FIG. 16, the first LED 161 and the second LED 162,
Third LED 163, fourth LED 164, fifth LED 16
In the LED 160 of No. 5 and the like, a pulse current was allowed to flow only for about 800 μs in the “time element” of 1 ms which is the cycle of the clock signal. Therefore, in the pachinko machine 101 of FIG. 10, about 2 out of the 1 ms “time element” that constitutes the “control unit time” in the gradation control of the LED 160.
The pulse current cannot flow through the LED 160 for 200 μs, which causes a slight difference between the actual brightness and the desired brightness due to the gradation control of the LED 160, which adversely affects the gradation control of the LED 160. Was being given.

Therefore, the present invention has been made to solve the above-mentioned problems, and a pachinko machine that controls the lighting mode of an LED, which is a light source of an electrical decoration, by data obtained by serial-parallel conversion. An object of the present invention is to provide a pachinko machine that matches the actual brightness and the desired brightness by controlling the gradation of the LED by using the enable terminal and the latch terminal of the digital IC circuit to which the LED is connected. It is an issue.

[0015]

The invention according to claim 1 made in order to solve this problem is the data obtained by the serial-parallel conversion of the lighting mode of the LED which is the light source of the electrical decoration. A pachinko machine for controlling, wherein a gradation control of the brightness of the LED is performed by the number of the time elements in which a pulse current is passed through the LED in a control unit time configured by a predetermined number of time elements which are clock signal periods. When performing, the enable terminal and the latch terminal of the digital IC circuit to which the LED is connected are used.

The invention according to claim 2 is the pachinko machine according to claim 1, wherein the LED is capable of emitting light of a plurality of colors.

In the pachinko machine of the present invention having such characteristics, for example, when the signal of the enable terminal of the digital IC circuit is "L" and when the signal of the latch terminal of the digital IC circuit is "L", The LED connected to the digital IC circuit is in the operating state, and the state in which the pulse current can flow to the LED is maintained. Then, after the transmission of the serial data to the digital IC circuit is completed, the signal at the enable terminal of the digital IC circuit is set to “H”, and the digital IC is
The LED connected to the circuit is disconnected, but the pulse current is L because the signal at the latch terminal of the digital IC circuit is "L".
The state that can flow to the ED is retained.

After that, the signal at the latch terminal of the digital IC circuit is set to "H" so that the pulse current cannot flow through the LED, while the serial data is converted into parallel data. Then, the signal at the latch terminal of the digital IC circuit is set to "L" again, but at this time, the digital I
Since the signal of the enable terminal of the C circuit is "H", the LED connected to the digital IC circuit is disconnected and the pulse current does not flow to the LED.

However, next, the signal at the enable terminal of the digital IC circuit is set to "L", the LED connected to the digital IC circuit is set to the operating state, and based on the data obtained by the serial-parallel conversion, LED pulse current
It is ready to be washed.

Then, the control of the pulse current flowing through the LED is performed in synchronization with each clock signal transmitted to the digital IC circuit. Further, in the control unit time constituted by a predetermined number of time elements which are clock signal periods, L
The gradation control of the brightness of the ED is performed, and the lighting mode of the LED, which is the light source of the electrical decoration, is controlled by the data obtained by the serial-parallel conversion.

That is, the pachinko machine of the present invention is a pachinko machine that controls the lighting mode of the LED, which is the light source of the electrical decoration, by the data obtained by the serial-parallel conversion, and is a digital IC to which the LED is connected. By using the enable terminal and the latch terminal of the circuit, for example, even if the signal of the enable terminal of the digital IC circuit is set to “H” and the LED connected to the digital IC circuit is disconnected, If the signal is “L”, the state in which the pulse current can flow to the LED is held, so that the pulse current can flow to the LED at most of the time elements that constitute the control unit time in the gradation control of the LED. Therefore, it is possible to match the actual brightness and the desired brightness by controlling the gradation of the LED.

In particular, when a gradation-controlled LED is used that is capable of emitting light of a plurality of colors, the degree of brightness of each of the red, blue, and green elements greatly affects the emission color of the LED. Therefore, the effects described above can be exerted significantly.

Incidentally, "H" and "L" of the signal of the enable terminal and the signal of the latch terminal of the digital IC circuit are used for convenience of explanation, and the relative relationship between "H" and "L" is shown. If they are the same, "H" and "L" can be used in reverse.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the pachinko machine 11 of the present embodiment is provided with a central electric decoration 13, a pair of shoulder electric decorations 14, a lower electric decoration 15, and other electric decorations on a game area 12. . Further, on the frame 16 above the game area 12, an electric decoration such as a frame electric decoration 17 is provided.

In this respect, the light sources of these illuminations include the central illumination 13, the pair of shoulder illuminations 14, and the lower illumination 1.
5 and a part of the frame decoration 17, a plurality of mono-color LEDs 18 capable of emitting a single color are used. Further, a plurality of multi-color LEDs 19 capable of emitting a plurality of colors are used in a part of the frame decoration 17.

That is, in the frame decoration 17, FIG.
As shown in FIG. 1, 16 multi-color LEDs 19 capable of emitting light of a plurality of colors are provided as a first LED 19A and a second LE 19A.
D19B, third LED19C, fourth LED19D, fifth
LED19E, sixth LED19F, seventh LED19G,
8th LED19H, 9th LED19I, 10th LED1
9J, 11th LED19K, 12th LED19L, 1st
3LED19M, 14th LED19N, 15th LED1
9O and the 16th LED 19P are mounted on the substrate 20. The substrate 20 is also equipped with 31 mono-color LEDs 18 capable of emitting a single color.

As the multi-color LED 19, the one shown in the front view of FIG. 3 and the side view of FIG. 4 is used. That is, as shown in FIG. 3 and FIG.
D19 is a base 91 molded with six pins 95.
In addition, a red chip 92, a blue chip 93, and a green chip 94 are sealed with an epoxy resin. In particular,
The brightness of the multi-color LED 19 is controlled in eight steps, as will be described later. Here, the "gradation control" in eight steps is performed for each of the red, blue, and green chips 92, 93, 94. Since this is performed, a total of 8 × 8 × 8 = 512 colors can be emitted. Each multi-color LED 19 is equipped with one Zener diode for protecting the blue chip 93 and the green chip 94.

In the pachinko machine 11 shown in FIG. 1, the lighting mode of the multi-color LED 19 and the like is controlled as shown in FIG.
As shown in the block diagram of FIG.
That is, the main control CPU 2 is provided on the substrate 21 of FIG.
2, main control ROM 23, main control RAM 2
4, input / output port 25, etc. are installed. Then, the main control CPU 22 uses the main control ROM 2
3 and the control pattern and other technical information stored in the main control RAM 24 and the like, the variation pattern signal is transmitted to the substrate 31 and the like in FIG. 5 via the input / output port 25.

On the other hand, on the substrate 31 of FIG. 5, the LED lighting control CPU 32, the LED lighting control ROM 33, and the LE are provided.
A D-lighting control RAM 34, an input / output port 35 (corresponding to a "digital IC circuit"), etc. are mounted. Further, the input / output port 35 includes 16 multi-color LEDs 19 (first LED 19A to 16th LED).
19P) and the like are connected.

Specifically, as shown in FIGS. 6 and 7,
Eight multi-color LEDs 19 (first LED 19A to eighth LED 19H) connected to the line of the first COM 39 are connected to output terminals 46 to 53 of the three input / output ports 35, and eight connected to the line of the second COM 38. Multi-color LED 19 (9th LED 19I to 16th LED)
19P) is an output terminal 46 of three input / output ports 35
~ 53. At this time, 16 multi-color LEDs 19 (first LED 19A to 16th LED 19P)
Is divided into 3 chips each of red, blue and green chips.
It is connected to the output terminals 46 to 53 of the output port 35. Furthermore, eight multi-color LEDs 19 (first LED 19A to eighth LED 19) connected to the line of the first COM 39.
H) is connected to a power source (not shown) via the transistor 37 and is connected to the line of the second COM 38, and the eight multi-color LEDs 19 (9th LED 19I to 16th LE).
D19P) is connected to a power supply (not shown) via the transistor 36.

In the input / output port 35 of FIG. 7, reference numeral 41 is an input terminal for serial data, reference numeral 42 is a clock terminal, reference numeral 43 is a latch terminal, and reference numeral 44 is an enable terminal. Reference numeral 45 is an output terminal for serial data, and reference numeral 54 is an R-EXT terminal.

Then, the LED lighting control CPU 3 of FIG.
2 through the input / output port 35 (separately provided in addition to FIGS. 6 and 7) based on the control method and other technical information stored in the LED lighting control ROM 33, the LED lighting control RAM 34, and the like. According to the variation pattern signal received by the output terminal 46 of the input / output port 35.
Sixteen multi-color LEDs 19 (first LED 19A to 16th LED1) connected to 53 (see FIGS. 6 and 7)
9P) and other lighting modes are controlled.

In this respect, the LED lighting control CPU 32 is
By transmitting serial data to the input terminal 41 (see FIGS. 6 and 7) of the input / output port 35, 1
The lighting modes of the six multi-color LEDs 19 (first LED 19A to 16th LED 19P) and the like are controlled.

Specifically, as shown in FIG. 8, the enable signal 6 of the enable terminal 44 of the input / output port 35 is used.
When 1 is “L” and the latch signal 62 of the latch terminal 43 of the input / output port 35 is “L”, the multi-color LED 19 connected to the output terminals 46 to 53 of the input / output port 35 operates. In this state, the state in which the pulse current can flow to the multi-color LED 19 is maintained. However,
At this time, the first COM 39 through the transistor 37
Line is disconnected from the power supply, so the second COM3
8 multi-colored LEDs 19 connected to 8 lines
A state in which a pulse current can flow is held in (9th LED 19I to 16th LED 19P).

After the transmission of the serial data 63 to the input terminal 41 of the input / output port 35 is completed, the enable signal 61 of the enable terminal 44 of the input / output port 35 is set to "H", and the input / output port 35 is set. Of the multi-color LED 19 connected to the output terminals 46 to 53 of the second CO
Disconnect the M line 38 from the power supply, but input / output port 3
Since the latch signal 62 of the latch terminal 43 of 5 is "L",
Eight multi-color LEDs 19 (9th LED 19I to 16th LED 19P) connected to the line of the 2nd COM 38
The state in which the pulse current can flow is maintained at.

After that, the latch signal 62 of the latch terminal 43 of the input / output port 35 is set to "H", and the second COM 38
The eight multi-color LEDs 19 (9th LED 19I to 16th LED 19P) connected to the line are set so that no pulse current can flow, while the input / output port 35 converts serial data into parallel data. Then, the latch signal 62 of the latch terminal 43 of the input / output port 35 is set to "L" again, but at this time, the enable signal 61 of the enable terminal 44 of the input / output port 35 is still "H", so the input・ Output port 35
Multi-color LED connected to the output terminals 46-53 of
19 is disconnected and the pulse current is multicolor L
It does not flow to ED19.

However, next, the enable signal 61 of the enable terminal 44 of the input / output port 35 is set to "L", and at the same time, the first COM 39 is transmitted via the transistor 37.
8 multi-color LEDs 19 (first LED 19A) connected to the power supply and connected to the first COM 39 line.
~ 8th LED19H) to the operating state, based on the data obtained by the serial-parallel conversion, eight multi-color LED19 (first LED19A ~ 8th LED1
9H) is set in a state in which a pulse current can flow.

The same is true thereafter, and the input / output port 3
5 after the transmission of the serial data 63 to the input terminal 41 of 5 is completed, the enable terminal 44 of the input / output port 35
Of the multi-color L connected to the output terminals 46 to 53 of the input / output port 35 with the enable signal 61 of "H".
While disconnecting the ED 19, the first COM line 37 is disconnected from the power supply via the transistor 36, but
Since the latch signal 62 of the latch terminal 43 of the output port 35 is “L”, the eight multi-color LEDs 19 (first LED 19A to 8L) connected to the line of the first COM 37.
A state in which a pulse current can flow is maintained in ED19H).

After that, the latch signal 62 of the latch terminal 43 of the input / output port 35 is set to "H", and the first COM 37
While the pulse current cannot flow in the eight multi-color LEDs 19 (first LED 19A to eighth LED 19H) connected to the line of the input / output port 3
At 5, the serial data is converted into parallel data. Then, the latch signal 62 of the latch terminal 43 of the input / output port 35 is set to "L" again, but at this time, the enable signal 61 of the enable terminal 44 of the input / output port 35 is still "H", so the input・ Output port 35
Multi-color LED connected to the output terminals 46-53 of
19 is disconnected and the pulse current is multicolor L
It does not flow to ED19.

However, next, the enable signal 61 of the enable terminal 44 of the input / output port 35 is set to "L", and at the same time, the second COM 38 is turned on via the transistor 36.
Of the multi-color LED 19 (9th LED19I) connected to the power line and connected to the line of the second COM 38.
~ 16th LED19P) to the operating state, serial-
Based on the data obtained by parallel conversion, eight multi-color LEDs 19 (9th LED19I to 16th LE)
D19P) is set to a state in which a pulse current can be passed.

By repeating the above, 16 multi-color LEDs 19 (first LED 19A to 16th LE) connected to the output terminals 46 to 53 of the input / output port 35.
D19P) is turned on by eight multi-color LEDs 19 (first LED 19A to eighth LED 19) connected to the line of the first COM 37 via the transistors 36 and 37.
H) and eight multi-color LEDs 19 (9th LED 19I to 16th LED) connected to the line of the 2nd COM 38.
19P) and control separately.

In this regard, in the input / output port 35, 16 multi-color LEDs 19 (first LED 19A to 16th LED) are passed through the transistors 36 and 37 while the enable signal 61 of the enable terminal 44 is "H".
19P) is separated from the circuit, 16 multi-color LEDs 19 are alternately arranged based on the parallel data converted from the serial data 63 at every 1 ms which is the period of the clock signal transmitted to the clock terminal 42.
A pulse current can be passed through the (first LED 19A to 16th LED 19P).

Furthermore, in the pachinko machine 11 of this embodiment, 16 multi-color LEDs 19 (first LED 19) are used.
When controlling the brightness of the A to 16th LEDs 19P), gradation control of 8 steps as shown in FIG. 13 is performed in the same manner as the conventional technique. That is, 1 ms, which is the period of the clock signal transmitted to the clock terminal 42 of the input / output port 35, is set as the "time element", and the "control unit time" is formed by the seven "time elements". Of the seven “time elements” of “unit time”, 16 multi-color LEDs 19 (first LED 19A to 16th LED 19)
P) depending on the number of "time elements" in which a pulse current is applied to each multi-color LED 19 (first LED 19A to 16L).
ED19P) brightness is controlled.

Therefore, as shown in FIG.
The brightness of the multi-color LED 19 is the largest when the pulse current is passed through the multi-color LED 19 in all the "time elements" of the seven "time elements" of the "control unit time". As shown in "Control unit time"
The brightness of the multi-color LED 19 is the smallest when the pulse current is passed through the multi-color LED 19 with one "time element" among the seven "time elements". Also,
The brightness of the multi-color LED 19 decreases as the number of “time elements” for passing a pulse current to the multi-color LED 19 decreases to 6, 5, 4, 3, and 2 ((b) of FIG. 13, (C), (d), (e),
(F)). As shown in (h) of FIG. 13, when the pulse current is not applied to the multi-color LED 19 in all the “time elements” of the seven “time elements” of the “control unit time”, The color LED 19 has no brightness.

Then, as shown in FIG. 14, the gradation control is continuously performed for "control unit time", whereby the lighting mode of the multi-color LED 19 can be controlled. For example, in (α) of FIG. 14, each “control unit time”
Multi-color LE in all 7 "time elements" of
A pulse current is applied to D19, and from the player's perspective,
It seems that the multi-color LED 19 continues to light up in the brightest state. Further, in (β) of FIG. 14, the pulse current is not passed through the multi-color LED 19 in all of the seven “time elements” of each “control unit time”, and the multi-color LED 19 is turned off from the player's perspective. Seems to continue. Further, in (γ) of FIG. 14, as the “control unit time” progresses, the number of “time elements” that pass the pulse current to the multi-color LED 19 decreases by one, and from the player's point of view, The color LEDs 19 appear to gradually fade. In addition, in (δ) of FIG. 14, as the “control unit time” progresses, the number of “time elements” for passing a pulse current to the multi-color LED 19 increases by one, and from the player's perspective The color LEDs 19 appear to become progressively brighter.

Therefore, as shown in FIG. 15, for example, if a pulse current is applied to five adjacent multi-color LEDs 19 or the like in seven "time elements" of each "control unit time", then five adjacent multi-color LEDs 19 will be generated. Single multi-color LED 19
In the above, each light emission can be controlled so as to move by pulling a tail. Such control is performed by the multi-color LED 19
It utilizes the agile flashing and flashing of lights, which cannot be realized with conventional lamps.

14 and 15, between the last "time element" of "control unit time" and the first "time element" of the next "control unit time", for convenience of explanation, It is wider than between each "time element", but is actually the same as between each "time element".

Further, in the pachinko machine 11 of the present embodiment, 16 multi-color LEDs 19 (first LED 19A to 16th LED 1) are provided via the transistors 36 and 37.
9P) is separated from the circuit, and 16 multi-color LEDs 19 (first one) are alternately arranged based on the parallel data converted from the serial data 63 at every 1 ms which is the cycle of the clock signal transmitted to the clock terminal 42. 1L
Since a pulse current is passed through the ED 19A to the 16th LED 19P), t which is the “control unit time” is 14 (ms).

From the above, the pachinko machine 11 of the present embodiment
Then, the above-mentioned 16 multi-color LEDs 19 (first
The control of the pulse current flowing through the LEDs 19A to 16th LEDs 19P) is performed in synchronization with each cycle of the clock signal transmitted to the clock terminal 42 of the input / output port 35. In addition, 7 of "time element" which is a clock signal cycle
Multi-color L of the "control unit time"
Depending on the number of "time elements" that flow a pulse current through the ED19,
By controlling the gradation of the brightness of the multi-color LED 19,
The lighting mode of the multi-color LED 19 which is the light emission source of the frame decoration 17 is controlled by the data obtained by the serial-parallel conversion.

That is, the pachinko machine 11 of the present embodiment
Then, the multi-color LED which is the light emission source of the frame decoration 17
A pachinko machine for controlling the lighting mode of 19 using data obtained by serial-parallel conversion,
By using the enable terminal 44 and the latch terminal 43 of the input / output port 35 to which the ED 19 is connected,
For example, when the enable signal 61 of the enable terminal 44 of the input / output port 35 is set to “H”, the multicolor L connected to the output terminals 46 to 53 of the input / output port 35.
Even if the ED 19 is disconnected, if the latch signal 62 of the latch terminal 43 of the input / output port 35 is “L”, the state in which the pulse current can flow to the multi-color LED 19 is held. Specifically, as shown in FIG.
A pulse current of about 993 μs can be supplied to the ED 19 out of the “time element” of 1 ms which is the cycle of the clock signal. Therefore, since the pulse current can be passed through the multi-color LED 19 in most of the “time elements” that make up the “control unit time” in the gray-scale control of the multi-color LED 19, the actual brightness by the gray-scale control of the multi-color LED 19 and The desired brightness can be matched.

Particularly, in the multi-color LED 19 whose gradation is controlled in 8 steps, the red, blue and green chips 92, 93,
The degree of brightness of 94 is 5 of the multi-color LED 19.
Since the 12 emission colors are greatly affected, the above-described effects can be exerted significantly.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the invention. For example, “H” and “L” of the enable signal 61 of the enable terminal 44 of the input / output port 35 and the latch 62 signal of the latch terminal 43 are used for convenience of description, and are “H” and “L”. If the relative relationship of "" is the same, "H" and "L" can be used reversely for description.

Further, in the pachinko machine 11 of the present embodiment, the gradation-controlled LED uses the multi-color LED 19 capable of emitting a plurality of colors, but a mono-color LED capable of emitting a single color is used. Even when used, the effects described above can be exhibited.

[0054]

The pachinko machine of the present invention is a pachinko machine which controls the lighting mode of the LED, which is the light source of the electrical decoration, by the data obtained by the serial-parallel conversion.
By using the enable terminal and the latch terminal of the digital IC circuit to which D is connected, for example, the digital I
Even if the signal of the enable terminal of the C circuit is set to "H" and the LED connected to the digital IC circuit is disconnected, if the signal of the latch terminal of the digital IC circuit is "L", a pulse current can flow to the LED. Since the pulse current can be passed to the LED by most of the time elements that constitute the control unit time in the gradation control of the LED by holding the LED, the actual brightness and the desired brightness by the gradation control of the LED can be obtained. Can be matched.

In particular, when a gradation-controlled LED that can emit light of a plurality of colors is used, the brightness of each of the red, blue, and green elements greatly affects the LED emission color. Therefore, the effects described above can be exerted significantly.

Note that "H" and "L" of the signal of the enable terminal and the signal of the latch terminal of the digital IC circuit are used for convenience of explanation, and the relative relation between "H" and "L" is used. If they are the same, "H" and "L" can be used in reverse.

[Brief description of drawings]

FIG. 1 is a front view of a pachinko machine according to an embodiment of the present invention (game nails are omitted).

FIG. 2 is a pachinko machine multi-L according to an embodiment of the present invention.
It is a front view of the board | substrate with which ED was mounted.

FIG. 3 is a front view of a multi-color LED used in a pachinko machine according to an embodiment of the present invention.

FIG. 4 is a side view of a multi-color LED used in a pachinko machine according to an embodiment of the present invention.

FIG. 5 is a block diagram of a pachinko machine according to an embodiment of the present invention.

FIG. 6 is a circuit diagram of a pachinko machine according to an embodiment of the present invention.

FIG. 7 is a front view of the input / output ports of the pachinko machine according to the embodiment of the present invention.

FIG. 8 is a diagram showing timings of signals for controlling a lighting mode of a lamp of a pachinko machine according to an embodiment of the present invention.

FIG. 9 is a diagram for explaining gradation control of LED brightness of a pachinko machine according to an embodiment of the present invention.

FIG. 10 is a front view of a conventional pachinko machine (game nails are omitted).

FIG. 11 is a block diagram of a conventional pachinko machine.

FIG. 12 is a diagram showing timings of signals for controlling a lighting mode of a lamp of a conventional pachinko machine.

FIG. 13 is a diagram for explaining gradation control of brightness of LEDs of a conventional pachinko machine.

FIG. 14 is a diagram for explaining gradation control of brightness of LEDs of a conventional pachinko machine.

FIG. 15 is a diagram for explaining gradation control of the brightness of LEDs of a conventional pachinko machine.

FIG. 16 is a diagram for explaining a problem of gradation control of the brightness of the LED of the conventional pachinko machine.

[Explanation of symbols]

11 Pachinko machines 17 frame illumination 19 Multi-color LED 35 input / output ports 43 Latch terminal 44 Enable terminal 63 serial data t Control unit time

Claims (2)

[Claims] 1. A pachinko machine that controls a lighting mode of an LED, which is a light emitting source of an electrical decoration, by data obtained by serial-parallel conversion, the control being configured by a predetermined number of time elements that are clock signal cycles. When the gradation control of the brightness of the LED is performed by the number of the time elements in which a pulse current is passed through the LED in the unit time, the enable terminal and the latch terminal of the digital IC circuit to which the LED is connected are connected. A pachinko machine characterized by being used. 2. The pachinko machine according to claim 1, wherein the LED is capable of emitting light of a plurality of colors.