JP5560453B1 - PWM output device, PWM output method, and game machine - Google Patents

Abstract

A PWM output device that can be formed with a simple and low-cost circuit configuration and is easy to perform on / off control at a high switching frequency and fine adjustment of a duty ratio.
A signal output unit for outputting an arbitrary signal, a counter unit for detecting a counter value as an output time of the signal output from the signal output unit, and a signal output from the signal output unit. A data acquisition unit 13 that detects a data value as a signal value, and an on / off control unit 14 that controls on / off of the PWM signal based on the data value and the counter value. The on / off control unit 14 sets the data value to the counter value. Calculate the remainder value obtained by dividing the multiplied value by the maximum value that at least one of the counter value and the data value can take, add the data value to the calculated remainder value, and any value Contrast with the threshold value, the PWM signal is turned on when the sum value is larger than the threshold value, and the PWM signal is turned off when the sum value is less than or equal to the threshold value.
[Selection] Figure 1

Description

  The present invention relates to a PWM output device, a PWM output method, and a game machine that control current and the like by PWM control.

  2. Description of the Related Art Conventionally, there has been known a method of performing control using PWM (Pulse Width Modulation, pulse width modulation) when controlling the amount of power. In this method, the amount of electric power and the magnitude of the signal are changed by changing the duty ratio of the PWM signal formed by periodically output pulses (the ratio of the ON signal to the ON / OFF period of the PWM signal). Etc. As a configuration for changing the duty ratio, a configuration described in Patent Document 1 is known. In this configuration, a data converter, a segment signal converter, a common signal converter, and a PWM signal converter are provided, the data converter forms a signal indicating lighting / extinction for each segment, and the segment signal converter is a PWM signal. A signal having a pulse width different from that of the common signal, which is assigned to each period by the common signal converter. The PWM converter forms a PWM signal based on the signal formed by the segment signal converter and the common signal converter. As a result, a plurality of channels that output PWM signals (output systems that output the respective PWM signals; the same applies in this specification) are formed, and as shown in FIG. Like the PWM signal 201 having a large duty ratio and the PWM signal 202 having a small duty ratio in the channel 2, a desired PWM signal is output in each channel (see, for example, Patent Document 1).

Japanese Patent No. 4840107

  However, in the invention described in Patent Document 1, when a PWM signal having a different period is generated and output in each channel as shown in FIG. 4 (b), the PWM signal of each channel is output. For each PWM signal converter that generates a signal, a different counter (configuration for defining a time that is a reference for turning on and off the PWM signal) must be provided, and a large number of counters are required, and the entire PWM signal output device There is a problem that the configuration of the system becomes complicated. Here, for example, in the case of controlling the lighting / extinguishing state and light quantity of the lighting device such as the LED by the PWM signal, in order to prevent the flickering of the lighting device, it is necessary to repeat the lighting / extinguishing in a fine cycle, When trying to perform such lighting control in the invention described in Patent Document 1, it is inherently difficult to finely adjust the duty ratio of the PWM signal. Therefore, there is a problem that the circuit configuration of each of the converters described above becomes large and the cost is high.

  The present invention has been made in view of the above problems, and can be formed with a simple and low-cost circuit configuration, and can easily perform on / off control at a high switching frequency and fine adjustment of a duty ratio. It is an object to provide a method and a gaming machine.

To solve such problems, an invention according to claim 1, a PWM output unit for performing on-off control of the lit of the driving and lighting system of the apparatus disposed in the game machine, as any signal The number of unit times is measured in units of unit time as individual time zones formed by a signal output means for outputting the output signal and a reference time zone that is a predetermined time zone for a predetermined number of times. a counter means for detecting a counter value as an output time of the output signal by a data acquisition means for detecting the data value of the signal value of the output signal outputted from the signal output means, said data values and On / off control means for controlling on / off of each PWM signal based on the counter value, and the unit time is obtained by equally dividing the reference time zone into a number based on an exponent multiple of a predetermined number of 2. The The reference time zone and the unit time are used in common for all the PWM controls used in all the PWM controls, and are formed by dividing the reference time zone into one or a plurality of equal parts. Is set as one cycle of the PWM signal used in each PWM control, and the one cycle is set separately for each PWM signal. The counter value, the output level of the PWM signal, and a predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using a binary number, and the counter means , by measuring the number of the unit time, and detects the counter value of each of the PWM signal, in the on-off control means, said counter value and said The output level and a predetermined threshold WM signal, using the binary numbers, each of the maximum value is set as a value relative to the index times the predetermined number of 2, the on-off control means, said counter value A value obtained by multiplying the value obtained by dividing the data value by the maximum value that can be taken by at least one of the counter value and the data value is calculated, and the data value is added to the calculated remainder value. The sum value added is compared with the threshold value. When the sum value is larger than the threshold value, each PWM signal is turned on, and the sum value is less than the threshold value. each of the PWM signal by turning off the if, in one period of each of the PWM signal set separately based on a common said reference time, and characterized by performing on-off control of each of the PWM signal That.

  The invention according to claim 2 is characterized in that, in addition to the configuration according to claim 1, the maximum value is a value obtained by subtracting 1 from an exponential multiple of 2.

  According to a third aspect of the present invention, in addition to the configuration according to the first or second aspect, the threshold value is a value obtained by subtracting 1 from the maximum value.

According to a fourth aspect of the present invention, in addition to the configuration according to any one of the first to third aspects, the on / off control means uses the following formulas (A) and (B) to calculate the value of the sum. And the threshold value, the on / off control means turns on the PWM signal when Out = 1 in the equation (A), and the output when Out = 0 in the equation (B). The PWM signal is turned off.
Out = 1 (A)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data> 2 ⁿ −2, Out = 0 (B)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data ≦ 2 ⁿ −2,
Out: PWM signal output (1 = on, 0 = off)
Data: PWM output level (an integer value from 0 to 2 ⁿ −1) in the corresponding channel that outputs the PWM signal
Seqcnt: Time series counter common to all channels (0 → 2 ⁿ -2 integer value is repeated)

The invention described in claim 5, a PWM output method for performing on-off control of lit driving and lighting system of the apparatus disposed in a gaming machine, a signal for outputting an output signal as any signal an output procedure, as the unit the unit time as individual time periods which are formed by time being the reference time zone which is a predetermined time period a predetermined number, said output signal by measuring the number of the unit time A counter procedure for detecting a counter value as an output time, a data acquisition procedure for detecting a data value as a signal value of the output signal output from the signal output procedure, and the data value and the counter value, respectively The unit time is set as a value obtained by equally dividing the reference time zone into a number based on an exponent multiple of a predetermined number of 2, Base The time zone and the unit time are used in common in all the PWM controls used in all the PWM controls, and each time zone formed by equally dividing the reference time zone into one or more. Is set as one cycle of the PWM signal used in each of the PWM controls, and the one cycle is set separately for each of the PWM signals, and each of the PWM signals includes the counter value and the The output level of the PWM signal and the predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using binary numbers, and in the counter procedure, by measuring the number, it is detected the counter value of each of the PWM signal, in the on-off control procedure, out of the counter value and the PWM signal The level and a predetermined threshold value, using a binary number respectively set maximum value as a value relative to the index times the predetermined number of 2, in the on-off control procedure, the data value to the counter value the value obtained by multiplying, calculates the value of the remainder at least one is divided by the maximum possible value of the counter value and the data value, plus the data value to the value of the remainder issued the calculated sum the value of the comparison with a threshold value of the sum is turned on each of the PWM signal is greater than the threshold value, respectively when the value of the sum is less than the threshold value by turning off the said PWM signal, in one period of each of the PWM signal set separately based on a common said reference time, and performs on-off control of each of the PWM signal

  The invention according to claim 6 is a gaming machine, and based on the PWM output device according to any one of claims 1 to 4, on / off control of the lighting device disposed in the gaming machine body is performed. It is characterized by that.

According to the first and fifth aspects of the invention, the remainder obtained by dividing the value obtained by multiplying the counter value by the data value by the maximum value that can be taken by at least one of the counter value and the data value is obtained. The sum value obtained by adding the data value to the calculated remainder value is compared with a predetermined threshold value. When the sum value is larger than the threshold value, the PWM signal is turned on, By turning off the PWM signal when the value is equal to or smaller than the threshold value, PWM signals having different lengths of one cycle can be easily formed based on a combination of numerical values of the counter value and the data value. For this reason, a plurality of PWM signals having different periods can be formed based on the operation of one counter unit. Therefore, PWM signals having different periods and duty ratios can be obtained from a plurality of channels with a simple and low-cost circuit configuration. Can be generated. In the above calculation, by changing the counter value and the data value, the cycle and duty ratio of the PWM signal can be changed at a fine level. Therefore, the cycle of the PWM signal is shortened and the duty ratio is changed finely. Therefore, it is possible to easily increase the switching frequency of the PWM signal and to finely adjust the duty ratio. Thereby, it can be formed with a simple and low-cost circuit configuration, and on-off control at a high switching frequency and fine adjustment of the duty ratio can be easily performed.

  According to the second aspect of the present invention, the maximum value is a value obtained by subtracting 1 from an exponent multiple of 2 so that the calculation can be performed based on the counter value and the data value adapted to the digital signal. Therefore, the circuit configuration can be simplified and the operation speed can be increased. In particular, a remarkable effect can be obtained when the on / off control means is configured by a digital circuit.

  According to the invention of claim 3, the threshold value is a value obtained by subtracting 1 from the maximum value, and can be turned off or on when the value obtained by the calculation is other than the maximum value, On-off control can be simplified, and the operation of the comparison means can be simplified and speeded up.

  According to the fourth aspect of the present invention, the present invention can be realized based on the calculation of a specific expression.

  According to the sixth aspect of the present invention, on-off control, output control, lighting control, etc. of an electric device provided in a gaming machine can be formed with a simple and low-cost circuit configuration, and on-off at a high switching frequency. It is possible to realize control that facilitates control and fine adjustment of the duty ratio.

It is a functional block diagram which shows the whole structure of the PWM output device which concerns on embodiment of this invention. It is a flowchart which shows the operation procedure of a PWM output device same as the above. It is a conceptual diagram of the PWM signal output by a PWM output device same as the above. (A) The conceptual diagram of the PWM signal output by the conventional PWM output device, (b) The conceptual diagram of the PWM signal which a problem may occur in the conventional PWM output device.

[Basic configuration]
1 to 3 show a first embodiment of the present invention.

  FIG. 1 is a functional block diagram showing the overall configuration of the PWM control apparatus according to the first embodiment.

A PWM output device 1 shown in FIG. 1 is used to control lighting of a plurality of lighting devices (not shown) provided in a gaming machine such as a pachinko machine. In other words, the PWM output device 1 can be used to turn on / off lighting devices (not shown) used in gaming machines and change the amount of light periodically or whenever an event such as “big hit” occurs. The PWM output device 1 shown in FIG. 1 based on the above is disposed in one gaming machine main body (not shown). However, the PWM output device 1 may be provided separately from the gaming machine main body (not shown), and one PWM output device 1 is provided in each of a plurality of gaming machine main bodies (not shown). You may perform lighting control of an illuminating device (not shown). Further, the PWM output device 1 may be used for drive control of equipment other than lighting equipment (not shown) provided in the gaming machine main body (not shown), such as a motor.

  The PWM output device 1 includes at least one CPU 21, and the operation of the PWM output device 1 is controlled by processing of commands and data in the CPU 21. Further, the PWM output device 1 includes a RAM 22 that functions as a work area in the processing of the CPU 21, a ROM 23 that stores various data, an EEPROM (not shown), a magnetic disk (not shown), and the like. Note that the PWM output device 1 may include various components for sequence control instead of the CPU 21, and the operation may be controlled by the operation of the configuration.

  The PWM output device 1 includes a signal output unit 11 as a “signal output unit”, a counter unit 12 as a “counter unit”, a data acquisition unit 13 as a “data acquisition unit”, and an on / off unit as an “on / off control unit”. A control unit 14 is provided. As shown in FIG. 1, the signal output unit 11, the counter unit 12, the data acquisition unit 13, and the on / off control unit 14 may be configured as hardware or realized by executing various programs in the CPU 21. It may be configured as a functional means.

The signal output unit 11 outputs an arbitrary signal as an “output signal” . Specifically, a signal set to be output at an arbitrary timing based on logic or a program, or a signal generated based on arbitrary data input to the PWM output device is output. The signal output from the signal output unit 11 may be a digital signal or an analog signal.

The counter unit 12 detects a counter value as an output time of a signal as an “output signal” output from the signal output unit 11. Specifically, for example, the counter unit 12 forms a unit time in which a time zone as a “reference time zone” divided every arbitrary time zone, for example, every second is further divided into arbitrary values, eg, 256 equal parts. Then, the counter value obtained by measuring the signal output time in unit time is detected. This counter value is related to the data value acquired by the data acquisition unit 13, and the correlation of the data value for each unit time is stored in a temporary storage area (not shown) formed in the RAM 22. .

  The data acquisition unit 13 detects a data value as a signal value of the signal output from the signal output unit 11. Specifically, the magnitude of an arbitrary value of the signal output from the signal output unit 11 is detected. The magnitude of the arbitrary value may be a voltage value of a signal, for example, but may be a current value or the like.

  The on / off control unit 14 controls on / off of the PWM signal based on the data value and the counter value. Specific contents of the control will be described later.

[Principle of control in the on / off control unit 14]
The on / off control unit 14 calculates a remainder value obtained by dividing the value obtained by multiplying the counter value by the data value by the maximum value that at least one of the counter value and the data value can take, and the calculated remainder value is calculated. The sum of the data values is compared with an arbitrary threshold value. When the sum value is larger than the threshold value, the PWM signal is turned on. When the sum value is less than the threshold value, the PWM signal is turned on. Turn off the signal.

Specifically, when outputting the PWM signal with an accuracy of 2 ⁿ bits (n ≧ 1), the on / off control unit 14 uses the following equations (A) and (B), and in the equation (A) When Out = 1, the PWM signal is turned on, and when Out = 0 in the formula (B), the PWM signal is turned off.
Out = 1 (A)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data> 2 ⁿ −2, Out = 0 (B)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data ≦ 2 ⁿ −2,
Out: PWM signal output (1 = on, 0 = off)
Data: PWM output level (an integer value from 0 to 2 ⁿ −1) in a corresponding channel that outputs a PWM signal. A value is configured based on the data value acquired by the data acquisition unit 13.
Seqcnt: a time series counter common to all channels (0 → 2 ⁿ -2 integer value is repeated). It is formed based on the counter value detected by the counter unit 12.

More specifically, for example, when a computer using the PWM output device 1 or a computer using the PWM output device 1 in a gaming machine (not shown) is an 8-bit computer, specifically, The on / off control unit 14 uses the following equations (C) and (D), turns on the PWM signal when Out = 1 in equation (C), and turns on the PWM signal when Out = 0 in equation (D). Control to turn off the.
Out = 1 ... (C)
However, when (Seqcnt × Data) mod ₂₅₅ + Data> 254, Out = 0 (D)
However, when (Seqcnt × Data) mod ₂₅₅ + Data ≦ 254,
Out: PWM signal output (1 = on, 0 = off)
Data: PWM output level (an integer value from 0 to 255) in a corresponding channel that outputs a PWM signal. A value is configured based on the data value acquired by the data acquisition unit 13.
Seqcnt: A time series counter common to all channels (the integer value of 0 → 254 is repeated). It is formed based on the counter value detected by the counter unit 12.

  By doing in this way, the following effects can be acquired.

First, in an 8-bit system, calculating the remainder of the value divided by the highest value of a numerical value represented by 8 bits (0 to 255 in decimal number, or 00000000 to 11111111 in binary number) is 255 from an arbitrary numerical value. Since it is equal to the value obtained by one or more times, the calculation is simple and fast. Further, in the above formulas (C) and (D), the calculation of (Seqcnt × Data) mod ₂₅₅ is {(integer of 0 to 254) × (integer of 0 to 255) mod ₂₅₅ }, and the on / off control unit 14, when calculating the above formulas (C) and (D), the remainder of (Seqcnt × Data) mod ₂₅₅ can be obtained by calculation other than division, so that division is virtually unnecessary in that part. become. Therefore, the calculation in the on / off control unit 14 can be performed easily and at high speed, and the configuration of the on / off control unit 14 may be simple.

  Next, Seqcnt is a count number that can be represented by an 8-bit numerical value (a total of 255 counts of 0 to 254 counts in decimal number). Using this Seqcnt, the expression (C) and By applying the formula (D), the cycle of the PWM signal becomes a fine cycle (specifically, “CH-A of the CH-A in the PWM signal 201 with respect to“ one cycle of seqcnt ”in FIG. 4B). (Refer to the relationship between “one PWM cycle” and “one PWM cycle of CH-B” in the PWM signal 202). Thereby, based on the operation of one counter unit 12, it is possible to output PWM signals with fine and different periods from a plurality of channels.

  As described above, by using the above formulas (C) and (D), the PWM output device 1 can be formed with a simple and low-cost circuit configuration in an 8-bit system, and on / off control at a high switching frequency is possible. And fine adjustment of the duty ratio can be easily performed.

In the above formula (C) and Formula (D), the maximum value of Seqcnt is 254 (minus 2 from ^{2 8),} (a value obtained by subtracting 1 from ^{2 8)} the maximum value 255 of the Data met Each of these is a value obtained by subtracting an arbitrary value (2 or 1 in this case) from the value of an exponent of 2. As a result, the calculation can be performed based on the counter value and the data value suitable for the digital signal, so that the circuit configuration can be simplified and the calculation speed can be increased. When configured, a remarkable effect can be obtained.

In the above formulas (C) and (D), the threshold value is 254 (a value obtained by subtracting 1 from the maximum value 255 of Data (2 = ⁸ )). Thereby, when the value obtained by the calculation is other than the maximum value, it can be turned off or on, the on / off control can be simplified, and the calculation of the on / off control unit 14 can be simplified and speeded up.

  These effects can also be achieved when the above formulas (A) and (B), which are generalized from the formulas (C) and (D), are applied. This can also be achieved when (A) and (B) are applied.

For example, when the PWM output device 1 is applied to a 16-bit system, the following effects (E) and (F) can be used in the on / off controller 14 to achieve the same effect as described above.
Out = 1 ... (E)
However, when (Seqcnt × Data) mod ₆₅₅₃₅ + Data> 65534, Out = 0 (F)
However, when (Seqcnt × Data) mod ₆₅₅₃₅ + Data ≦ 65534,
Out: PWM signal output (1 = on, 0 = off)
Data: PWM output level (an integer value from 0 to 65535) in a corresponding channel that outputs a PWM signal. A value is configured based on the data value acquired by the data acquisition unit 13.
Seqcnt: A time series counter common to all channels (the integer value of 0 → 65534 is repeated). It is formed based on the counter value detected by the counter unit 12.

Also, in the ²ⁿ power system other than the above, the same effects as described above can be obtained with the same configuration.

[Operation procedure]
FIG. 2 is a flowchart showing an operation procedure of the PWM output device 1 of this embodiment. Hereinafter, the operation of the PWM output device will be described with reference to FIG. Here, for convenience of explanation, a description will be given based on the case where the PWM output device 1 is used in an 8-bit system.

  First, in a gaming machine (not shown), in a periodic operation (for example, blinking of an LED that is intermittently performed regardless of the presence or absence of an event) or an occurrence of an event (for example, when a “big hit” occurs) (step S1) The signal output unit 11 outputs a signal set in advance by a program, wired logic, or the like (step S2, signal output procedure). In this embodiment, the signal output unit 11 outputs a digital signal, but may be an analog signal.

Then, based on the signal outputted from the signal output unit 11 in step S1, the counter unit 12 detects the counter value of the signal that will be output (step S3, the counter steps).

  Further, based on the signal output from the signal output unit 11 in step S1, the data acquisition unit 13 acquires the data value of the signal at an arbitrary time corresponding to the counter value detected in step S2 (step S4). , Data acquisition procedure).

  Next, the on / off control unit 14 applies the counter value acquired in step S3 and the data value acquired in step S4 to the equations (C) and (D) to calculate a PWM signal for each counter value. . Specifically, the on / off control unit 14 turns on the PWM signal when Out = 1 (“Out = 1” in step S5 → step S6, on / off control procedure), and turns off the PWM signal when Out = 0. (“Out = 0” in step S5 → step S7, on / off control procedure).

  If the operation or event continues after the procedure of step S6 or S7 (“No” in step S8), the counter unit 12 increments the counter value and then performs the procedure of step S2 to step S6 or S7. repeat. This procedure is repeated until the operation and the event are completed (“Yes” in step S8).

  In the above procedure, the PWM signal 100 whose conceptual diagram is shown in FIG. 3 is generated. Specifically, as shown in the figure, the output of the PWM signal 100 is turned on at the position where the operation according to the procedure of steps S5 to S6 is performed in one arbitrary counter value, and the other arbitrary counter value The output of the PWM signal 100 is turned off at the places where the operations according to the steps S5 to S7 are performed. Note that the on / off control unit 14 can simultaneously output a plurality of PWM signals 100 having different periods from a plurality of channels based on the above procedure.

  As described above, in this embodiment, the on / off controller 14 divides the value obtained by multiplying the counter value by the data value by the maximum value that at least one of the counter value and the data value can take. A value is calculated, the sum of the calculated remainder value plus the data value is compared with an arbitrary threshold value, and if the sum value is greater than the threshold value, the PWM signal 100 is turned on. By turning off the PWM signal 100 when the sum value is less than or equal to the threshold value, the PWM signal 100 having a different length of one cycle can be easily formed based on the combination of the counter value and the data value. it can. Therefore, since a plurality of PWM signals 100 having different periods can be output based on the operation of one counter unit 12, PWMs having different periods and duty ratios can be obtained from a plurality of channels with a simple and low-cost circuit configuration. A signal 100 can be generated. In the above calculation, by changing the counter value and the data value, the cycle and duty ratio of the PWM signal 100 can be changed at a fine level. Therefore, the cycle of the PWM signal 100 is shortened and the duty ratio is made fine. The switching frequency of the PWM signal 100 can be increased, and fine adjustment of the duty ratio can be easily performed. Thereby, it can be formed with a simple and low-cost circuit configuration, and on-off control at a high switching frequency and fine adjustment of the duty ratio can be easily performed.

In the above embodiment, for example, in Formula (A) and Formula (B), the maximum value of Data is set to 2 ⁿ −1 and the maximum value of Seqcnt is set to 2 ⁿ −2, but not limited to this, Arbitrary n can be applied to the maximum value of Data or the maximum value of Seqcnt.

  The above embodiment is an exemplification of the present invention, and it is needless to say that the present invention is not limited to the above embodiment.

DESCRIPTION OF SYMBOLS 1 ... PWM signal output device 11 ... Signal output part (signal output means)
12 ... Counter section (counter means)
13: Data acquisition unit (data acquisition means)
14 ... ON / OFF control section (ON / OFF control means)
100, 201, 202 ... PWM signal

Claims (6)

A PWM output unit for performing on-off control of the lit of the driving and lighting apparatus disposed the equipment to the gaming machine,
Signal output means for outputting an output signal as an arbitrary signal;
As a unit time as an individual time zone formed by allocating a reference time zone, which is a predetermined time zone, to a predetermined number as a unit, by measuring the number of the unit time, as an output time of the output signal Counter means for detecting the counter value;
Data acquisition means for detecting a data value as a signal value of the output signal output from the signal output means;
On / off control means for controlling on / off of each PWM signal based on the data value and the counter value,
The unit time is set as a value obtained by equally dividing the reference time zone into a number based on an exponent multiple of a predetermined number of 2,
The reference time zone and the unit time are used in common in all the PWM controls used in all the PWM controls,
Each time zone formed by equally dividing the reference time zone into one or a plurality is set as one cycle of the PWM signal used in each PWM control,
The one period is set separately for each of the PWM signals,
In each PWM signal, the counter value, the output level of the PWM signal, and a predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using a binary number. And
The counter means detects the counter value of each PWM signal by measuring the number of unit times,
In the on / off control means, the counter value, the output level of the PWM signal, and a predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using a binary number. And
The on / off control means calculates a remainder value obtained by dividing a value obtained by multiplying the counter value by the data value by the maximum value that can be taken by at least one of the counter value and the data value. A value obtained by adding the data value to the remainder value is compared with the threshold value;
When the sum value is larger than the threshold value, the respective PWM signals are turned on, and when the sum value is less than the threshold value, the respective PWM signals are turned off .
A PWM output device that performs on / off control of each of the PWM signals in one cycle of each of the PWM signals set separately based on the common reference time .   2. The PWM output device according to claim 1, wherein the maximum value is a value obtained by subtracting 1 from an exponent multiple of 2. 3.   The PWM output device according to claim 1, wherein the threshold value is a value obtained by subtracting 1 from the maximum value. The on / off control means compares the sum value with the threshold value using the following formulas (A) and (B):
The on / off control means turns on the PWM signal when Out = 1 in the equation (A), and turns off the PWM signal when Out = 0 in the equation (B). Item 4. The PWM output device according to any one of Items 1 to 3.
Out = 1 (A)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data> 2 ⁿ −2, Out = 0 (B)
However, when (Seqcnt × Data) mod ₂ ⁿ ₋₁ + Data ≦ 2 ⁿ −2,
Out: PWM signal output (1 = on, 0 = off)
Data: PWM output level (an integer value from 0 to 2 ⁿ −1) in the corresponding channel that outputs the PWM signal
Seqcnt: Time series counter common to all channels (0 → 2 ⁿ -2 integer value is repeated) A PWM output method for performing on-off control of lit driving and lighting system of the apparatus disposed in the game machine,
A signal output procedure for outputting an output signal as an arbitrary signal;
As a unit time as an individual time zone formed by allocating a reference time zone, which is a predetermined time zone, to a predetermined number as a unit, by measuring the number of the unit time, as an output time of the output signal A counter procedure for detecting the counter value;
A data acquisition procedure for detecting a data value as a signal value of the output signal output from the signal output procedure;
An on / off control procedure for controlling on / off of each PWM signal based on the data value and the counter value,
The unit time is set as a value obtained by equally dividing the reference time zone into a number based on an exponent multiple of a predetermined number of 2,
The reference time zone and the unit time are used in common in all the PWM controls used in all the PWM controls,
Each time zone formed by equally dividing the reference time zone into one or a plurality is set as one cycle of the PWM signal used in each PWM control,
The one period is set separately for each of the PWM signals,
In each PWM signal, the counter value, the output level of the PWM signal, and a predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using a binary number. And
In the counter procedure, the counter value of each PWM signal is detected by measuring the number of unit times,
In the on / off control procedure, the counter value, the output level of the PWM signal, and a predetermined threshold value are set as values based on an exponential multiple of a predetermined number of 2 using a binary number. And
In the on-off control procedure, the data value obtained by multiplying a, calculates the value of the modulo least the maximum one can take of the counter value and the data value to the counter value, the the value of the sum of the calculated remainder value plus the data value, and the threshold value comparison,
Each PWM signal is turned on when the sum value is larger than the threshold value, and each PWM signal is turned off when the sum value is less than or equal to the threshold value . A PWM output method , wherein on / off control of each PWM signal is performed in one cycle of each PWM signal set separately based on the reference time .   A gaming machine that performs on / off control of a lighting device disposed in a gaming machine main body based on the PWM output device according to any one of claims 1 to 4.

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