RU2277005C1 - Method and device for automatic determination of winning combination when playing roulette - Google Patents

Abstract

FIELD: playing skills.

SUBSTANCE: method and device can be used for automatic determination of winning number and color of sector followed by visualization of winning combination when playing roulette. Ring of separator's cells is illuminated with modulated light signal. Code disc disposed under wheel of roulette and being aligned with it, is also illuminated with light signal. Disc is tightly connected wheel and contains information on disposition of numbers and on color of cells on separator's ring, which information is excess in relation to number of cells. Light signals reflected from ring of cells, ball of roulette and code disk are received and transformed into electric signals. Electric signal after being transformed from light signal, reflected from mentioned ball, is compared with current threshold level and is reduced to logic level which corresponds to zero or to unit. The signals received are processed by means of storing them while using excess of information at code disc. Signals are subject to analysis by means of comparing electric signals received from light signals reflected from mentioned ball with electric signals received from light signals reflected from code disc to determine number and color of separator's cell where the mentioned ball finds its place. Device for realization of the method has code disc disposed under wheel of roulette in alignment with the disc. The disc is tightly connected with the wheel and has information on disposition of cells and color of cells onto separator's ring, which information is excess comparing to number of cells of separator. Device also has pulse oscillator, at least one group of modulated light signal source which is oriented onto ring of separator, receiver of light signal reflected from ring of separator's cells and modulated electric signal processing unit, at least one light signal source which is oriented onto information contained on the disc. Device also has a group of at least first and second receiver of light signal reflected from code disc, which receivers are oriented onto information on disposition of numbers and color of cells onto separator's ring. Device has as well a group of at least first and second units for forming electric signal with preset logic levels and signal processing unit.

EFFECT: improved reliability of determination of winning combination; widened functional capabilities.

22 cl, 14 dwg

Description

The invention relates to a gaming technique, in particular to a roulette game technique, and can be used, in particular, for automatically determining a winning number and sector color with subsequent visualization of a winning combination when playing manual roulette.

A known method for automatically determining the winning combination when playing roulette (see RF patent No. 2122878, IPC A 63 F 5/00, published 10.12.1998), including lighting the ring numbers of the roulette wheel with a red light and infrared radiation, lighting the separator cell ring cylinder source of red light and the processing of reflected optical signals. Moreover, the reflected optical signal from the separator cells is used to determine the position of the ball, and the reflected optical signals of the numbers are used to determine the angular position and direction of rotation of the roulette wheel.

The known method does not provide a sufficiently reliable determination of the winning combination, since determining the winning number and calibrating the roulette wheel by reading and processing with the help of comparators information about the color fields of the roulette wheel in the presence of reflected glare and light noise inevitably leads to false positives of the comparators and errors in determining the number the cell in which the ball stopped.

A device for automatically determining the winning combination when playing roulette (see RF patent No. 2122878, IPC A 63 F 5/00, published 10.12.1998), containing a block of primary optical converters, including two photodetectors and a first source of directional illumination, block determination the zero position of the wheel, a unit for determining the direction of rotation of the wheel, a programmable memory unit, a digital indicator and a pulse generator, three comparators with an adjustable threshold of operation, three envelope detectors, a sex determination unit Expectations of the ball, the logical element "AND" and two blocks of logical processing. A second source of directional illumination and an infrared radiation source, the trigger input of which is connected to the second output of the pulse generator, are introduced into the block of primary optical converters. The second radiation source is designed to determine the direction of rotation of the cylinder.

The use in the known device of lighting systems with two different wavelengths of emitted light directed to the digital zone and the cell zone, leads to the cumbersome reader located high above the side of the wheel. Calibration of the device at the border of the green cell does not allow determining the position of the ball in the cell by the position of its center, which is an additional source of errors in the case of diffuse reflection of modulated light from the ball.

A known method for determining the position of the ball on the roulette wheel (see US patent No. 58836583, IPC A 63 P 5/02, published November 17, 1998) includes lighting the cylinder number ring with light from two spatially offset light sources, lighting the ring of cells of the cylinder separator with light to determine the presence of the ball, analysis of reflected light to determine the angular position of the cylinder inside the wheel and the position of the ball with respect to it, for which the illuminating light of at least one given wavelength is modulated, and the detected reflected light is comprises at least one similarly modulated wavelength, said wavelength is determined in advance depending on the relative luminance of the rotating cylinder.

The known method does not provide a sufficiently reliable determination of the position of the ball (winning number). This drawback is associated with the applied optical registration of color fields on the wheel cylinder, which is unreliable due to uncontrolled exposure to external light noise and is not invariant to the difference in color shades of wheels of various manufacturers.

A known system for determining the winning number when playing roulette (see US patent No. 6616530, including a rim (rim), inside of which is a cylinder having a ring of cells to hit the playing ball and a ring of numbers with colored areas located in a known sequence; a video camera mounted on the rim to create an image of the part of the roulette wheel, including at least one color region of the number and the corresponding cell.The video signal from the video camera is processed by the processor in two video fields - in the color area of the digital field and in the cell video field. In the first video field using the correlation mask method, the color of the selected area is determined, and after binding it to the green field of the “zero” mark, the sequence of digital field numbers is determined. In the second video field of the cells, the presence or absence in this ball cell. A special additional sensor generates a ball on the wheel rim. The winning number is determined using a separate microprocessor based on tions information received from these two video fields.

The disadvantage of this device is the exposure of the camcorder to the influence of external flare and bright glare, which makes it impossible to distinguish color information and distort the signal from the ball, displacing it in the cell area adjacent to the cell with the winning number. The need for image formation from the color field and from the field of cells leads to the need to place the video camera at a sufficient height above the side of the roulette wheel, which violates the design and can interfere with the game.

The closest set of essential features to the claimed technical solution is a method for automatically determining the winning combination when playing roulette (see RF patent No. 2211067, IPC A 63 F 5/02, published August 27, 2003), adopted as a prototype. The prototype method includes lighting with a modulated light signal of a ring of numbers of a roulette wheel, lighting with a modulated light signal of a ring of cells of a separator of a roulette wheel, receiving and analyzing reflected light signals to determine the sector in which the ball is located. Red light signals are usually used as light signals, and pulse modulation is used to modulate light signals.

In the known prototype method, the digital field is illuminated with an undigested light beam, and the direction of rotation of the wheel is determined by the alternation of color pulses in the region of the green cell “zero”. The known method does not provide a sufficiently reliable determination of the position of the ball (winning number) due to the fact that optical registration of color fields on the roulette wheel is used, which is unreliable due to uncontrolled exposure to external light noise and is not invariant to the difference in color shades of wheels of various manufacturers. The use of adjustable thresholds of comparators that determine the colors of the digital field require regular adjustment due to changes in the lighting level of the roulette wheel, as well as due to color distortion due to light interference, etc.

A device is known for automatically determining the winning combination when playing roulette (see RF patent No. 2211067, IPC A 63 F 5/02, published August 27, 2003), the closest in terms of essential features adopted for the prototype. The device comprises an information processing unit, a first modulated light signal source oriented to the number ring, a first reflected light signal receiver oriented to the number ring and connected to the information processing unit, a second modulated light signal source oriented to the separator cell ring, a second reflected light receiver a signal oriented to the ring of cells of the separator and connected to the information processing unit, the output of which is the output of the device.

The known prototype device does not provide reliable determination of the combination when playing manual roulette due to the influence of external flashes and bright glare, which makes it impossible to reliably distinguish between color information and distorting the signal from the ball. Calibration and reading of a digital field using an optoelectronic sensor located on board the roulette , does not allow to reduce the vertical size of the device, to provide high noise immunity from bright external glare and general intense illumination. Setting the device on roulette wheels with different shades of color requires reconfiguring the entire system of thresholds for comparators.

The objective of the proposed technical solution was the development of such a method of automatically determining a winning combination and implementing this method of a device that would improve the reliability of determining a winning combination by providing noise immunity in conditions of uncontrolled external exposure; and would also be invariant to the type of roulette and the color shades of the color of the separator cells and the digital field of the roulette wheel.

The task in terms of the method is solved by the fact that in the method of automatically determining a winning combination when playing roulette, the ring of separator cells is illuminated with a modulated light signal, the code disk placed under the roulette wheel coaxially with it and rigidly connected with it and containing information about the arrangement of numbers and the color of the cells on the separator ring, redundant with respect to the number of separator cells, receive light signals reflected from the ring of separator cells, the roulette ball and the code di ka and convert them into electrical signals. The electrical signal obtained from the light signal reflected from the said ball is compared with the current threshold level and brought to a logical level corresponding to zero or one, the received signals are processed by accumulating them using redundancy information on the code disk, and the signals are analyzed by comparing electrical signals, obtained from the light signals reflected from the ball, with electrical signals obtained from the light signals reflected from the code disk, for about definiteness of the number and color of the separator of the cell that contains the ball.

The use of electrical signals obtained by illuminating a code disk located under the roulette wheel coaxially with it and rigidly connected with it and containing information about the location of the numbers and the color of the cells on the separator ring, which is excessive in relation to the number of separator cells, makes it possible to operate manually roulette in the conditions of the whole complex of rapidly changing external interference of the gaming hall, to perform tight synchronization of the roulette wheel with an accuracy N times greater than the accuracy s attainable in the prior art (where N - coefficient redundancy code contained on the disk information relative to the number of separator cells).

It is advisable to illuminate the ring of separator cells with a modulated light signal with a wavelength lying in the range of 440-490 nm, focused in a vertical strip with a width d of a smaller ball diameter D _w and a length L equal to (1.5-2.0) D _w .

It is possible to illuminate the roulette wheel rim with an additional modulated light signal, receive light signals reflected from the said ball by two receivers of the reflected light signal spaced apart by a predetermined distance, analyze the electrical signals received when light signals are reflected from the ball to determine the presence of the ball on the roulette wheel rim and for determining at least one parameter of its motion.

As a parameter of the ball movement, it is possible to determine its speed at least at each revolution along the rim of the roulette wheel, the direction of the ball, the number of revolutions of the ball on the rim of the roulette wheel.

If we compare the obtained value of the velocity of the ball V _tech with a given threshold value of V _min , then with V _tech ≤V _min you can generate a signal for the command "bets are made".

Amplitude modulation, in particular pulse modulation, or modulation using harmonic functions can be used to modulate light signals.

The current threshold level can be formed in the form of an electrical signal obtained from a light signal reflected from the ring of cells of the separator in the absence of a ball.

The accumulation of electrical signals obtained from the reflected light signals from the ball can be achieved by summing the signals exceeding the threshold level for each N electrical signals received from the light signals reflected from the code disk and corresponding to one separator cell. In this case, it is possible to carry out a weighted comparison between themselves of the accumulated electrical signals obtained from the reflected light signals from the ball, which are in the zones of adjacent cells of the separator, and make the decision on the number of the cell in which the ball is located from the larger of the accumulated signals.

In terms of the device, the task is solved in that the device for automatically determining a winning combination when playing roulette contains a code disk located coaxially with it under the roulette wheel and rigidly connected with it and containing information about the location of numbers and color of cells on the separator ring, redundant with respect to to the number of separator cells, a pulse generator, at least one group of a modulated light signal source oriented to the cell ring of the separator, the receiver reflected from the cell ring the light signal separator and the modulated electrical signal processing unit, at least one light signal source oriented on the information on the location of the numbers and the color of cells on the separator ring contained in the code disk, a group of at least the first and second receivers of the light reflected from the code disk a signal oriented accordingly to said information on the arrangement of numbers and color of cells on the separator ring contained in the code disk, a group of at least the first and second blocks for generating an electric signal with predetermined logical levels, an information processing unit, wherein the first output of the pulse generator is connected to the input of the said modulated light signal source, the second output of the pulse generator is connected to the first input of the said modulated electric signal processing unit, the second input of which is connected to the output of the receiver reflected from the ring of cells of the separator of the light signal, the output of the processing unit of the electrical signal is connected to th input information processing unit to the second and third inputs which are respectively connected first and second receivers from the reflected light signal code disc via respective first and second blocks forming the electric signal with predetermined logic levels, the output information processing unit is an output device.

The use of a code disk containing information about the location of the numbers and the color of the cells on the separator ring, excessive in relation to the number of separator cells, as mentioned above, provides the possibility of the effective functioning of manual roulette in the conditions of the whole complex of rapidly changing external interference of the gaming room, to make tight synchronization of the roulette wheel .

The modulated electrical signal processing unit may include a first amplifier, a first demodulator and a first comparator, wherein the input of the first amplifier will be the second input of the modulated electrical signal processing unit, the output of the first amplifier is connected to the first input of the first demodulator, the second input of which is the first input of the modulated processing unit electrical signal, the output of the first demodulator is connected to the input of the first comparator, the output of which is the output of the module processing unit the generated electrical signal.

The first amplifier may include a first current-voltage converter, a first high-pass filter, a first low-pass filter and a first band-pass amplifier, wherein the first input of the first current-voltage converter is the input of the first amplifier, to the second input of which the output of the first filter is connected low-frequency, the input of which is connected to the first output of the first amplifier, the second output of which is connected to the input of the first high-pass filter, the output of which is connected to the input of the first strip amplifier, the output of which I It is output by the first amplifier.

The device may comprise at least one additional modulated light signal source oriented to the roulette wheel rim, a group of at least first and second receivers of the light signal reflected from the rim of the roulette wheel, spaced a predetermined distance, and an additional modulated electrical signal processing unit, this third output of the pulse generator is connected to the input of the said additional source of modulated light signal, the fourth output of the pulse generator in is connected to the first input of the additional modulated electrical signal processing unit, the second and third inputs of which are connected to the outputs of the first and second receivers of the light signal reflected from the rim of the roulette wheel, respectively, and the first and second outputs of the additional modulated electrical signal processing unit are connected to the fourth and fifth the inputs of the information processing unit.

An additional modulated electrical signal processing unit may include a second amplifier, a second demodulator, second and third comparators, while the first and second inputs of the second amplifier are respectively the second and third inputs of the additional modulated electrical signal processing unit, the output of the second amplifier is connected to the first input of the second demodulator, the second input of which is the first input of the additional block for processing the modulated electrical signal, the first and second outputs to orogo demodulator connected respectively to the input of the second comparator and to the input of the third comparator, the outputs of which are first and second supplementary outputs the modulated electric signal processing unit.

The second amplifier may include a second current-voltage converter, a second high-pass filter, a second low-pass filter and a second band-pass amplifier, while the first and second inputs of the second current-voltage converter are the first and second inputs of the second amplifier, the third input of which is connected to the output of the second low-pass filter, the input of which is connected to the first output of the second amplifier, the second output of which is connected to the input of the second high-pass filter, the output of which is connected to the input of the second field axial amplifier, the output of which is the output of the second amplifier.

The information processing unit may include a processor, at least one quartz resonator and an interface and a decision unit, wherein the first, second, third, fourth and fifth inputs of the processor are the first, second, third, fourth and fifth inputs of the information processing unit, to the sixth The input of the quartz resonator is connected to the input of the processor, the output of the processor is connected to the input of the interface, the output of which is the output of the information processing unit.

The output of the information block can be connected to a computer for further processing the results of determining the winning combination and displaying the results on the information board.

The inventive method and device for automatically determining a winning combination when playing roulette is illustrated by drawings, where

figure 1 shows a schematic illustration of a portion of a roulette wheel, including a roulette wheel and a rim, top view;

figure 2 shows a side view of a portion of the roulette wheel, including the roulette wheel and the rim;

figure 3 shows a schematic illustration of a part of the roulette wheel, including the roulette wheel and the rim, bottom view;

figure 4 shows a diagram of one embodiment of a device for implementing a method for automatically determining a winning combination when playing roulette;

5 is a diagram of another embodiment of a device for implementing a method for automatically determining a winning combination when playing roulette (B is a signal indicating the presence of a ball in the separator cell; D is a signal for determining the direction of rotation of the roulette wheel; Cl is a signal for determining the number of the separator cell and its color; Z - signal for determining edge positions of the cell number "0"; R ₁ - signal from one of the receivers of the reflected light signal passing the ball on the roulette wheel rim; R ₂ - another receiver signal reflected light a signal on the passage of the ball on the roulette wheel rim);

figure 6 shows one of the possible circuits of the processing unit of the modulated electrical signal;

Fig. 7 shows one of the possible schemes of an additional block for processing a modulated electrical signal;

on Fig shows one of the options for the first amplifier;

figure 9 shows one of the variants of the second amplifier;

figure 10 is a diagram of the information processing unit;

figure 11 gives an explanation of the method for determining the direction of rotation of the roulette wheel;

on Fig shows a fragment of the code disk at the location of the stroke for generating the signal Z, as well as signals Cl and D received at the second and third inputs of the information processing unit ("a" is the left edge of the signal Cl, "b" is the right edge of the signal Cl);

Fig.13 shows the sequence of operations carried out by the information processing unit;

on Fig rendered a continuation of the sequence of operations shown in Fig.13.

The simplest version of the device for automatically determining the winning combination when playing roulette (see Fig. 4) includes (see Fig. 1, Fig. 2, Fig. 3) a code disk 1 located under the roulette wheel 2 on one axis 3, rigidly associated with wheel 2 and containing information 5, 6, respectively: on the location of cells 8 and their color, on the location of the edge of the cell under the number "0" on the code disk 1 (signal Z is generated from this information) and information 7, which, in conjunction with the information 5 determine the direction of rotation of the wheel 2 roulette, while the disk 1 soda It contains information that is redundant with respect to the number of cells 8 of the separator 9, a pulse generator (GI) 10, one group of a modulated light signal (IMS) source 11 oriented to the cell ring 8 of the separator 9, the reflected light receiver (PSS) 12, oriented on the ring of cells 8 of separator 9, and the modulated electrical signal processing unit 13 (BOMES) it placed on the surface of the roulette board 14, or within the at least one light source 15 (EC _1), based on a code contained dis e 1 information 5 about the location of cells 8 and their color, information 6 about the location of the edge of the cell with the number "0" and information 7, which, together with information 5, allows to determine the direction of rotation of the roulette wheel 2, a group of the first light receiver 16 reflected from the code disk a signal (PSKD ₁ ) oriented to information 5 on the arrangement of cells 8 and their color contained on the code disk 1, and a second receiver 17 of a light signal reflected from the code disk (PSKD ₂ ) oriented to the information 6 on the code contained on the code disk 1 the position of the edge of the cell with the number "0" and information 7, which together with information 5 determines the direction of rotation of the roulette wheel 2, a group of the first electric signal generating unit 18 with predetermined logical levels (BFES ₁ and the second electric signal generating unit 19 with predetermined logical levels (BFES ₂ ), information processing unit 20 (BOI). In this case, the first output of the GI 10 is connected to the input of the mentioned IC 11, the second output of the GI 10 is connected to the first input of the BOMES 13, the second input of which is connected to the output of the MSS 12, the output of the BOMES 13 is connected to the first input of the BOI 20, to the second and third inputs of which are connected respectively PSKD ₁ 16 and PSKD ₂ 17 through respectively BFES ₁ 18 and BFES ₂ 19, the output of BOI 20 is the output of the device, which can be connected to the console of the dealer and the information board (not shown). The device may contain two or three groups of IC 11, PSS 12 and BOMES 13, the readings of which are compared to significantly increase the reliability of determining the cell number 8 of the separator 9. On the code disk 1, information 6 about the location of the cell under the number "0" can be placed separately from 7. In this case, the device will contain a second additional light source and an additional receiver of the light signal reflected from the code disk, oriented to the information on the location of the cells contained in the code disk 1 Menus number "0", which also increases the reliability of determination of the winning combination.

The device depicted in FIG. 5 is a further development of a device for automatically determining a winning combination when playing roulette. The device, in addition to the elements listed above, contains an additional source 21 of modulated light signal (DIMS) oriented to the rim 22 of the roulette wheel 2, a group of the first receiver 23 of the light signal reflected from the rim of the roulette wheel (OSS ₁ ) and the second receiver 24 reflected from the rim roulette wheel light signal (OSS ₂₎ oriented on the wheel rim 22 of the roulette 2 and spaced a predetermined distance on the circumference of the rim 22, an additional processing unit 25 of the modulated electrical signal (DBOMES), wherein Tp Tille output GOP 10 is connected to the input of dimsyl 21, the fourth output GOP 10 is connected to the first input DBOMES 25, second and third inputs of which are connected to the outputs respectively OSS _{January 23} and OSS _{Feb. 24,} and first and second outputs DBOMES 25 are connected respectively with the fourth and the fifth inputs of BOI 20.

Unit 13 for processing a modulated electrical signal (BOMES) includes (see Fig. 6) a first amplifier 26 (DC ₁ ), a first demodulator 27 (DO and a first comparator 28 (K ₁ ), while the input of DC ₁ 26 is the second input of BOMES 13 , the output of US ₁ 26 is connected to the first input D ₁ 27, the second input of which is the first input of BOMES 13, the output of the first D ₁ 27 is connected to input K ₁ 28, the output of which is the output of BOMES 13.

The first amplifier 26 (US ₁ ) includes (see Fig. 8) the first current-voltage converter 29 (PTN ₁ ), the first high-pass filter 30 (ФB4 ₁ ), the first low-pass filter 31 (low-pass filter ₁ ) and the first bandpass amplifier 32 (ПУО, wherein the first input of ПТН ₁ 29 is the input of US ₁ 26, to the second input of which the output of the low-pass filter ₁ 31 is connected, the input of which is connected to the first output of the ПТН ₁ 29, the second output of which is connected to the input of the high-frequency filter 30, the output of which is connected to the input PU132, the output of which is the output of US ₁ 26.

The additional block 25 for processing a modulated electrical signal (DBOMES) includes (see Fig. 7) a second amplifier 33 (US ₂ ), a second demodulator 34 (D ₂ ), a second comparator 35 (K ₂ ) and a third comparator 36 (K ₃ ), wherein the first and second inputs of DC ₂ 33 are respectively the second and third inputs of DBOMES 25, the output of DC ₂ 33 is connected to the first input D ₂ 34, the second input of which is the first input of DBOMES 25, the first and second outputs D ₂ 34 are connected respectively to the input To ₂ 35 and to the entrance of K ₃ 36, the outputs of which are the first and second outputs of DBOMES 25.

The second amplifier 33 (CS ₂₎ comprises (see. 9) of the second converter 37 "current-voltage" (STP _2), the second filter 38 of high frequency (HPF _2), a second low-pass filter 39 (LPF ₂₎ and a second bandpass amplifier 40 (PU ₂ ), the first and second inputs of the PTN ₁ 37 are the first and second inputs of the DC ₂ 33, to the third input of which the output of the low-pass filter ₂ 39 is connected, the input of which is connected to the first output of the DC ₂ 33, the second output of which is connected to the input of the HPF ₂ 38, the output of which is connected to the input of the PU ₂ 40, the output of which is the output of the DC ₂ 33.

The information processing unit (BOI) 20 includes (see FIG. 10) a processor 41 (PR), a quartz resonator 42 (KP ₁ ), and an interface 43 (IF), while the first, second, third, fourth, and fifth inputs of the PR 41 are the first, second, third, fourth and fifth inputs of BOI 20, the input KP ₁ 42 is connected to the sixth input of PR 41, the output of PR 41 is connected to the input of IF 43, the output of which is the output of BOI 20.

Sources of IC 11 and DIMS 21, receivers PSS 12, PSOK ₁ 23 and PSOK ₂ 24, generator GI 10, blocks BOMES 13 and DBOMES 25, block BOI 20 can be installed both on the surface of the bead 14 of the roulette wheel and inside the bead 14.

In the General case, the code disk 1 (see figure 2) can be mounted on the axis 3 under the wheel 2 of the roulette wheel at a random angle relative to the cell 8 under the number "0", and the source IC 11 and the receiver MSS 12 can also be on board 14 roulette or inside it anywhere. In this case, a preliminary adjustment of the device is carried out to find the Δ value that determines the difference between the position of the edge of the cell 8 under the number "0" of the separator 9 of the roulette wheel 2 registered by the MSS receiver 12 and the position of the information 6 on the location of the edge of the cell under the number "0" on the code drive 1, registered receiver PSKD116. To determine the boundary between cells 8 under the numbers "37" and "0", the ball is placed in cell 8 under the number "0" of the separator 9 of the roulette wheel 2 and the wheel 2 is twisted clockwise at a speed of at least 20 rpm. A prerequisite is the horizontal position of the roulette. Under these conditions, the ball is pressed to the edge of cell 8 under the number "0", which is taken beyond the border between cells 8 under the numbers "37" and "0". The Δ value determined during the adjustment of the device described above is stored in the non-volatile memory of the processor 41 and taken into account during further operation of the device. Alignment of the device must be carried out at each change of position of the source IC 11 and receiver MSS 12 on board 14 roulette.

The inventive method for automatically determining a winning combination when playing roulette is illustrated by the example of the operation of the device depicted in figure 4.

After turning on the device and starting the game, the modulated light signal generated by the IC 11 source illuminates the ring of cells 8 of the separator 9. It is advisable to use the wavelength of the light 16 signal of the IC 11 source from the blue spectral region, i.e. in the range 440-490 nm, since in this case, as the authors showed, the signal reflected from the ring of cells 8 of the separator 9 does not depend on the color of the cells 8. To reduce light loss and maintain invariance to the position of the ball inside the cell 8 of the separator 9 the light signal generated by the IC 11 source can be focused in the direction of movement of the ball into a vertical strip of width d, smaller than diameter D _w , and length (1.5-2.0) · D _w , using, for example, cylindrical optics. Calculations show that narrowing the beam to 3 mm while maintaining its vertical size, corresponding to the calculated spot diameter, reduces the loss factor by an order of magnitude, to modulate light signals using amplitude modulation. To modulate light signals, you can use amplitude modulation, pulse modulation, modulation using harmonic functions. Simultaneously with the illumination, the rings of cells 8 are illuminated by a light signal generated by the source of IC ₁ 15, the code disk 1 (see figure 2, figure 3), placed under the roulette wheel 2 coaxially with it and rigidly connected with it and containing information 5 about the location cells 8 and their color, redundant with respect to the number of cells 8 of the separator 9, information 6 about the location of the cell edge at the number "0" and information 7, which, together with information 5, determines the direction of rotation of the roulette wheel 2. The MSS receiver 12 receives the light signal reflected from the ring of cells 8 of the separator 9 and converts it into an electrical signal, which is fed through the second input of the BOMES 13 to the input of the amplifier US ₁ 26 (see Fig. 6). In the amplifier US ₁ 26 (see Fig. 8) in the PNT ₁ 29 block, covered by deep feedback through the low-pass filter ₁ 31, the electrical signal is converted from the current signal into a voltage signal and through the high-pass filter ₁ 30, which limits the passband from above, the signal is fed to PU ₁ 32, where it is amplified to the level of reliable detection. From the output of DC ₁ 26, the signal is supplied to the demodulator D ₁ 27, synchronized by pulses of GI 10, from D ₁ 27 the signal is sent to the comparator K ₁ 28, in which the received signal is compared with the current threshold level, which is formed in proportion to the average illumination of the roulette wheel 2, and bringing the signal to a predetermined logical level, for example, corresponding to zero or one, depending on the absence or presence of a ball in any cell 8 (signal B). From the output of K ₁ 28, signal B is fed to the first input of the BOI 20. The PSKD1 receiver 16, oriented to information 5 on the location of cells 8 and their color contained on the code disk 1, and the PSKD217 receiver, oriented to information 6 about the location of the cell edge "0" and information 7, which, in conjunction with information 5, determines the direction of rotation of the roulette wheel 2, receives reflected light signals and converts them into electrical signals, which are respectively supplied to BFES ₁ 18 and BFES ₂ 19, in which the signals are reduced to logic level (signals Cl, Z, and D, respectively), corresponding, for example, to zero or one, and respectively arrive at the second and third inputs of the BOI unit 20. Information redundancy on code disk 1 can be created, for example, by encoding each cell with 8 N symbols on code disk 1. For example, code disk 1 can be divided into 304 sectors (in this case, N = 8), each of which can be assigned its own serial number M. One of the encoding options for such information is shown in Fig. 11, where a fragment is shown code disk 1 and the state of the signals Cl and D at the output, respectively, BFES 1 18 and BFES 2 19. Two ring tracks of black and white strokes plotted on code disk 1 (5 - from which the signal Cl is taken and 7 - from which the signal D is taken), are divided into 152 pairs of black and white strokes and offset relative to each other by the width of one stroke. Bar 6, (corresponding to M = 0), by which signal Z is generated, can be applied on the third track of code disk 1 (in this case, the signal reflected from it is received by an additional PSKD receiver) or on track 7 (see Fig. 12). The set of pulses generated by the code disk 1 is a stable sequence of signals rigidly connected with the angle of rotation of the roulette wheel 2. The offset strokes of the tracks 5 and 7 relative to each other by the width of one stroke allows you to determine the direction of rotation of the wheel 2 of the roulette wheel. When the wheel 2 rotates to the left, the left front "a" of the Cl signal will increase (see Fig. 11), and D = 1 is fixed on it, and when the wheel 2 rotates to the right, the right front "b" of the Cl signal will increase, and along it the state D = 0 is fixed. To increase the reliability of determining the position of the ball in the cell 8 of the separator 9 in the BOI 20, the received signals B are processed by accumulating them according to a sample of pulses of the signal Cl within each of the cells 8, during the passage of which by the IC 11 the signal B is formed. the accumulated electrical signals B obtained from the reflected light signals from the ball, which appeared in the areas of adjacent cells 8 of the separator 9 in order to select the maximum value of this signal, which is compared with the value M + Δ = K of the signal Cl to determine the number and color of the cell 8 of the separator 9, in which the ball is located. Carried out during this analysis, the sequence of operations shown in Fig.13 and Fig.14. The beginning of each game is the start of rotation of the wheel 2 of roulette. When signal Z arrives, the previous value of signal B (indicated by B _old ) is set to 0, the value of M is set to 0 when the wheel 2 rotates to the right, and when the wheel is rotated to the left, M is set to 38 · N. From this moment, the M value of the signal Cl begins. Upon receipt of the signal Cl and signal D, it is determined whether the value of the signal D = 1 (wheel 2 rotates to the left) or the value of the signal D = 0 (wheel 2 rotates to the right) corresponds to the positive edge of the signal Cl. In the first case, the unit is subtracted from the value of M, and in the second case, the unit is added to the value of M. Further, when the wheel 2 rotates to the right, it is checked whether M 38 · N is equal, and when the wheel 2 rotates to the left, it is equal to M zero. If this condition is met, then the counter is reset (M = 0 - for the case of rotation of the wheel to the right; M = 38 · N for the case of rotation of the wheel to the left), if - no, then check whether signal B. has arrived. If signal B is not received, then the next signal Cl is expected to appear, upon receipt of which all the operations indicated above after its arrival are repeated. If signal B is received, then it is checked whether N is the new value of M. Multiple. If M is not a multiple of N, then the next signal Cl is expected, upon the occurrence of which the subsequent operations described above are repeated. If M turns out to be a multiple of N, then it is checked, the value of B is compared with B _old . In the case when B turns out to be greater than or equal to B _{old, the} value of B _old becomes B. If the value of B turned out to be less than B _old , then the value of the signal Cl equal to the current value K = M + Δ determines the number and color of cell 8 of the wheel separator 9 2 roulettes in which the ball is located. From BOI 20 through IF 43, data on the winning number and color of cell 8 are sent to the central computer for further processing of the results of determining the winning combination and displaying the results on the information board.

The speed V _{k of} rotation of the roulette wheel 2 can be determined by counting the number of pulses of the signal Cl passed by PSKD ₁ 16 for a fixed time interval specified by the number of pulses of the quartz resonator KP ₁ 42, for example, in one second. Every second in BOI 20, the value of the rotation speed of the roulette wheel 2 is determined.

Figure 5 shows a variant of the claimed device, which allows you to further determine the presence and direction of rotation of the ball along the rim 22 of the bead 14 of the roulette wheel. In this embodiment, the devices illuminate the rim 22 of the roulette wheel 2 with a modulated light signal from the DIMS source 21, and the light signal reflected from the rim 22 is registered by the receivers ПСОК ₁ 23 and ПСОК ₂ 24, spaced apart by a predetermined distance around the circumference of the rim 22, which convert it into electrical signals, which come respectively through the second and third inputs of the DBOMES 25 unit to the first and second inputs of the amplifier US ₂ 33 (see Fig. 7). In the amplifier US ₂ 33 (see Fig. 9) in the PNT ₂ 37 block, covered by deep feedback through the low-pass filter ₂ 39, the electrical signals are converted from the current signal into a voltage signal and through the high-pass filter ₂ 38, which limits the passband from above, the signals are fed to PU ₂ 40, where they are amplified to the level of reliable detection. From the output of DC ₂ 33, the signals are fed to the demodulator D ₂ 34, synchronized by the pulses GI 10, from D ₂ 34 the signals are sent respectively to the comparators K ₂ 35 and K ₃ 36, in which the received signals are compared with the current threshold level, which is formed in proportion to the average value the illumination of the rim 22, and bringing the signals to a logical level corresponding to zero or one, depending on the presence or absence of the ball on the rim 22. From the output of K ₂ 35 and K ₃ 36, the signals R ₁ and R ₂ are respectively supplied to the fourth and fifth inputs of the BOI 20. In the absence of a ball on the rim 22, the signals R ₁ and R ₂ are in the state of a logical unit. When the ball passes through the rim 22, the signals R ₁ and R ₂ take turns in the zero state. The direction of movement of the ball on the rim 22 is determined in BOI 20 according to the order of receipt of the signals R ₁ and R ₂ .

The speed V _tech of the ball’s movement along the rim of the roulette wheel 22 is determined in BOI 20 by measuring the time between two consecutive passes of the ball past PSOK ₁ 23 (or PSOK ₂ 24). This time is measured by counting the number of pulses specified by KP ₁ 42, laid between two successive passes of the ball. The device allows you to compare the obtained value of speed U _tech with a given threshold value of V _min and at V _tech ≤V _{min to} generate a signal for the command "bets are made".

Were made prototypes of the variants of the claimed devices depicted in figure 4 and figure 5. Testing a manual roulette equipped with these samples confirmed the reliability and accuracy of determining the automatic determination of a winning combination by the claimed method.

Claims (21)

1. A method for automatically determining a winning combination when playing roulette, characterized in that the ring of separator cells is illuminated with a modulated light signal, a code disk placed coaxially under the roulette wheel, rigidly connected with it and containing information about the location of the numbers and the color of the cells the separator ring, redundant with respect to the number of separator cells, receive light signals reflected from the ring of separator cells, the roulette ball and the code disk, convert them into electrical signals; the electric signal obtained from the light signal reflected from the said ball is compared with the current threshold level and brought to a logical level corresponding to zero or one, the received signals are processed by accumulating them using redundancy of information on the code disk, and the signals are analyzed by comparing electrical signals, obtained from the light signals reflected from the ball, with electrical signals obtained from the light signals reflected from the code disk, for about and color non-determination of the cell separator, wherein said ball is located. 2. The method according to claim 1, characterized in that the ring of cells of the separator is illuminated by a modulated light signal with a wavelength lying in the range of 440-490 nm. 3. The method according to claim 1, characterized in that the ring of cells of the separator is illuminated by a modulated light signal focused into a vertical strip of width d, smaller than the diameter D _{w of the} ball, and a length L equal to (1.5-2.0) D _w . 4. The method according to claim 1, characterized in that the rim of the roulette wheel is illuminated with an additional modulated light signal, light signals reflected from said ball are received by two receivers of a reflected light signal spaced apart by a predetermined distance, electrical signals obtained by reflecting light signals from said ball are analyzed , to determine the presence of said ball on the rim of the roulette wheel and to determine at least one parameter of its movement. 5. The method according to claim 4, characterized in that as a parameter of motion of said ball, its speed is determined at least at each revolution along the rim of the roulette wheel. 6. The method according to claim 5, characterized in that the obtained value of said speed V _{tech is} compared with a predetermined threshold value of V _min and, at V _tech ≤V _min , a signal is generated for the “bets made” command. 7. The method according to claim 4, characterized in that, as a parameter of motion of said ball, the direction of its movement is determined. 8. The method according to claim 4, characterized in that the number of revolutions of the ball on the wheel rim of the roulette wheel is determined as a parameter of motion of said ball. 9. The method according to claim 1, characterized in that amplitude modulation is used to modulate the light signals. 10. The method according to claim 9, characterized in that for modulating the light signals using pulse modulation. 11. The method according to claim 9, characterized in that for modulating the light signals using modulation using harmonic functions. 12. The method according to claim 1, characterized in that the threshold level is formed in the form of an electrical signal obtained from a light signal reflected from the ring of cells of the separator in the absence of a ball. 13. The method according to claim 1, characterized in that the accumulation of the aforementioned electrical signals obtained from the reflected light signals from the ball is carried out by summing said signals exceeding the threshold level for each N electrical signals received from the light signals reflected from the code disk, and corresponding to one separator cell, where N is the redundancy coefficient of the information contained on the code disk with respect to the number of separator cells. 14. The method according to item 13, wherein the weighted comparison of the accumulated electrical signals obtained from the reflected light signals from the ball, caught in the areas of adjacent cells of the separator, is made, and the largest of the accumulated signals makes a decision on the cell number in which there is a ball. 15. Device for automatically determining a winning combination when playing roulette, including a code disk placed under the roulette wheel coaxially with it, rigidly connected with it and containing information about the location of the numbers and color of cells on the separator ring, redundant with respect to the number of separator cells, generator pulses, at least one group from a source of modulated light signal oriented to the ring of cells of the separator, a receiver reflected from the ring of cells of the separator of the light signal and the processing unit of a dummy electric signal of at least one light signal source oriented to the above-mentioned information on the arrangement of numbers and color of cells on the separator ring contained in the code disk, a group of at least the first and second receivers of the light signal reflected from the code disk oriented to the code disk the mentioned information about the location of the numbers and the color of the cells on the separator ring, a group of at least the first and second electric signal generation units Ala with predetermined logical levels, an information processing unit, while the first output of the pulse generator is connected to the input of each of the mentioned sources of the modulated light signal, the second output of the pulse generator is connected to the first input of each of the mentioned blocks of the modulated electrical signal, the second input of which is connected to the output of the reflected receiver from the ring of cells of the light signal separator, the output of the electric signal processing unit is connected to the first input of the information processing unit, which the second and third inputs of which are connected, respectively, the first and second receivers of the light signal reflected from the code disk through, respectively, the first and second electric signal generating units with logical levels, the output of the information processing unit is the output of the device. 16. The device according to clause 15, wherein the modulated electrical signal processing unit includes a first amplifier, a first demodulator and a first comparator, wherein the input of the first amplifier is the second input of the modulated electrical signal processing unit, the output of the first amplifier is connected to the first input of the first demodulator the second input of which is the first input of the modulated electrical signal processing unit, the output of the first demodulator is connected to the input of the first comparator, the output of which is the output of the modulated electrical signal processing unit. 17. The device according to clause 16, wherein the first amplifier includes a first current-voltage converter, a first high-pass filter, a first low-pass filter and a first band-pass amplifier, while the first input of the first current-voltage converter is an input the first amplifier, to the second input of which the output of the first low-pass filter is connected, the input of which is connected to the first output of the first amplifier, the second output of which is connected to the input of the first high-pass filter, the output of which is connected to the input of the first olosovogo amplifier whose output is the output of the first amplifier. 18. The device according to p. 15, characterized in that it contains at least one additional source of modulated light signal oriented to the rim of the roulette wheel, a group of at least first and second receivers of the light signal reflected from the rim of the roulette wheel, spaced a predetermined distance and an additional block for processing the modulated electric signal, while the third output of the pulse generator is connected to the input of the said additional source of the modulated light signal, the fourth One pulse generator is connected to the first input of the additional modulated electrical signal processing unit, the second and third inputs of which are connected to the outputs of the first and second receivers of the light signal reflected from the rim of the roulette wheel, respectively, and the first and second outputs of the additional modulated electrical signal processing unit are connected to the fourth and fifth inputs of the information processing unit. 19. The device according to p. 18, characterized in that the additional processing unit of the modulated electrical signal includes a second amplifier, a second demodulator, second and third comparators, while the first and second inputs of the second amplifier are respectively the second and third inputs of the additional processing unit of the modulated electrical signal , the output of the second amplifier is connected to the first input of the second demodulator, the second input of which is the first input of an additional electrically modulated processing unit of the signal, the first and second outputs of the second demodulator are connected respectively to the input of the second comparator and to the input of the third comparator, the outputs of which are the first and second outputs of the additional block for processing the modulated electrical signal. 20. The device according to claim 19, characterized in that the second amplifier includes a second current-voltage converter, a second high-pass filter, a second low-pass filter and a second band-pass amplifier, while the first and second inputs of the second current-voltage converter are the first and second inputs of the second amplifier, to the third input of which the output of the second low-pass filter is connected, the input of which is connected to the first output of the second amplifier, the second output of which is connected to the input of the second high-pass filter, the output of which connected to the input of the second strip amplifier, the output of which is the output of the second amplifier. 21. The device according to clause 15, wherein the information processing unit includes a processor, at least one quartz resonator and an interface, while the first, second, third, fourth and fifth inputs of the processor are the first, second, third, fourth and fifth inputs of the information processing unit, the input of the quartz resonator is connected to the sixth input of the processor, the output of the processor is connected to the input of the interface, the output of which is the output of the information processing unit.

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