RO131620B1 - Photoelectric system for monitoring a token game played in a casino - Google Patents

Description

The present invention relates to a photoelectric system for monitoring valuable casino chips, colored chips from a game of roulette and betting boxes from card games.

It is known that in most casinos the chips that are in the float trays are of the usual plastic or ceramic type. This type of chip does not allow real-time and accurate monitoring of the financial situation on the gaming tables, nor does it prevent their theft for counterfeiting purposes.

To remedy this drawback, a patent system is known from international patent application WO 2011010795 A, which is applicable to a token in which a microchip is incorporated for identification by means of radio frequency means (RFID) which include an integrated circuit and an antenna connected to it. The RFID antenna has a frequency that is equal to or greater than 20 MHz and is equal to or less than 25 MHz. The disadvantage of this system is that it cannot be applied to ordinary chips (without a microchip).

The technical solution of US Pat. No. 2006/199649 A1 is also known, which is also based on the processing of signals obtained by means of a drive-head drive mechanism by means of which a photograph is taken of the pattern on the edge of the chips and their color. , in order to obtain a financial statement. The disadvantage of this system is due to its mechanical complexity which in principle makes it less reliable and based on more complicated processing of monitoring data.

A solution that can be applied to chips that do not have built-in chips is known from US Pat. No. 6254002 B1, according to which the security can be improved for any circular token in a casino, by using magnetic reading means, which can be applied to it. The token is constructed with at least a first, second, and a third set of magnetically readable information attached and forms a source of magnetic readable information. Each set of magnetically readable information may have magnetic elements containing a fiber, magnetic materials, filaments or strips, which can be read both mechanically, depending on the location of the information on the token, or electrically, through an electrical circuit by taking them and transforming them. in a digital signal. The information is transmitted through a scanning device.

Also for the purpose of monitoring chips that have not incorporated chips, the solution of patent application GB 2227347 A is known, according to which a chip validation system is provided with an optical detection unit comprising a light source - phototransistor, a lens, token-mounted and light-detecting devices associated with a microprocessor that determine whether a tested token has predetermined optical characteristics.

Both the solution in US Pat. No. 6254002 B1 and that in GB. ordinary chips.

Also known is the solution of identifying and monitoring chips on a casino table, which describes a chip with a disc-shaped body with a groove, and the components of a light emitting device, a radio, are inserted into the groove. controlled, which consists of a microchip a light source connected to the microchip by some circuits. Monitoring is performed by a remote processor that retrieves information from a microchip memory block. This solution has the disadvantage that it cannot be applied to the identification of ordinary chips.

For the purpose of monitoring tokens of the usual type in floats, patent 1 RO 128273 B1 is known, which comprises a system for monitoring tokens of values which do not have an integrated identification chip. This system consists of a token tray, with 3 12 rows for the placement of valuable tokens, in the positions of the tokens are arranged some phototransistors, one for each token, which transmit 5 an electrical signal depending on detection or not of the chip next to it, the signals from the phototransistors being processed by a specialized electronic circuit that provides an output 7 analog signal, taken by the modules 1/0 of a programmable automaton, which performs data acquisition, processing and transmission to a central server on which is installed 9 a specialized software application that has the role of storing all the information in a central database, and which allows both the monitoring of a game table in real time and the generation of 11 reports necessary for the team casino management.

The disadvantage of this system is that it depends on the ambient light and automatically when the dealer works on the tray, its balance is erroneous because the shadow made by the dealer influences the photoelectric sensors. 15

It is also known that in a casino the value chips have predefined colors, for example red is assigned to chips with a value of 5, green is assigned to chips with 17 value of 25, black is assigned to chips with a value of 100 and so on.

Another drawback of the system is that it does not recognize the color of the token fact 19 for which it can influence the balance of the float if there are no tokens of the same color (respectively value) on the strings. 21

The technical problem solved by the system, according to the claimed invention, is to monitor the chips from several game tables, regardless of the type of chips, their color 23 and the ambient light, and to identify the color of the chips placed in a row to keep a proper record of the balance. 25

A system for monitoring a game of chips played in a casino, consisting of at least one float, each containing 1 ... n rows of value chips, 1 ... n rows of 27 colored chips and 1 ... In betting boxes from card games, it is characterized in that each of the floats is provided with a concave optical guide in which an electronic module 29 is fitted with photoelectric sensors (6), for each token, on one of the sides of the float there is a light source consisting of a series of 31 LEDs in infrared, one LED for each token, with wavelength of visible spectrum, infrared or ultraviolet, depending of the optical sensors used, on the other side 33 of the float being arranged some color sensors for counting and identifying the color of the chips. 35

According to another aspect of the invention, the concave optical guide facilitates the propagation of light from the light source as well as the phenomena of reflection and diffraction. 37

According to another aspect of the invention, the electronic module equipped with optical sensors for counting and identifying the color of chips with photoelectric sensors for identifying the value of chips and the value of betting boxes contains a microcontroller that takes information from sensors, calculates the balance of the game table and associates it with the dealer present at 41 game tables, through a dedicated software application, which has the role of storing all the information in a central database to allow both monitoring of the game table, in real time 43, and the generation of reports necessary for the casino management team.

According to another aspect of the invention, the microcontroller on each electronic module 45 of each float (picks up the signals from the photoelectric sensors and / or the color optical sensors by means of comparator-type integrated circuits with bridge output and performs the data acquisition , as well as processing their transmission to a central server via a switch

According to another aspect of the invention, all the outputs of the comparators are connected by means of an output resistor to a common potential, thus obtaining at the output a linear voltage varying according to the number of sensors affected by light, which is taken up by means of a analog-to-digital converter and interpreted by the microcontroller, thus determining the number of blocked sensors, respectively the number of chips present in the row.

An embodiment of the system according to the invention is given below in connection with FIG. 1 ... 8, which represents:

- fig. 1, float view of the photoelectric system for monitoring a token game played in a casino according to the invention;

- fig. 2, the block diagram of the photoelectric system for monitoring a token game played in a casino;

- fig. 3, the diagram of the electronic module of the photoelectric system for monitoring a token game played in a casino;

- fig. 4, photo location of sensors of the photoelectric system for monitoring a game with color chips, according to the invention;

- fig. 5, view of the location of sensors of the photoelectric system for monitoring a game with colored chips at the roulette game, according to the invention;

- fig. 6, the diagram of the electronic module of the photoelectric system for monitoring a game with colored chips at the roulette game, according to the invention;

- fig. 7, view of the placement of sensors of the photoelectric system for monitoring the betting boxes from card games, according to the invention;

- fig. 8, diagram of the electronic module of the photoelectric system for monitoring the betting boxes from card games, according to the invention.

The photoelectric system for monitoring a game of chips played in a casino, according to the invention, consists of several floats F1 ... Fn, each with 1 ... n rows of 1 value chips, 1 ... n 2 rows of chips and 1 ... n boxes 3 betting from card games. Each of the floats F1 ... Fn is provided with a concave optical guide 4 in which an electronic module 5 with some photoelectric sensors 6 is mounted, for each token separately.

In one of the sides of the float F1 ... Fn is located its own light source 7 consisting of a series of infrared LEDs, one LED for each token. The light source 7 can have a wavelength in the visible, infrared or ultraviolet spectrum depending on the optical sensors used.

The concave optical guide 4 facilitates the propagation of light from the source 7 as well as the reflection and diffraction phenomena.

On the other side of the float F1 ... Fn are arranged some 8 color sensors which attest to the fact that all the chips 2 are of the same color.

The electronic module 5 is equipped with optical sensors 8 for counting and identifying the color of chips 2, the value of chips 1 and the value of betting boxes 3 and a microcontroller 9 that takes information from sensors, calculates the balance of the game table and associates it with dealer C1 ... Currently at the game tables.

The microcontroller 9 on each electronic module 5 of each float F1 ... Fn performs the acquisition of data, as well as the processing of their transmission to a central server S through a switch 10. On this microcontroller 5 is installed a dedicated software application, which has the role to store all the information in a central database 11 to allow both the monitoring of the game table, in real time, and the generation of the necessary reports to the casino management team.

Following the real-time analysis of the data and statistical information taken from the central S-1 server, decisions can be made in order to optimally relocate the croupiers to the gaming tables.

At the same time the decisions and all that means data processing are sent to the 3 central S server for further storage and analysis.

Optical sensors 6 for chip counting are arranged equidistantly, one 5 for each chip in some holes (not shown) placed at the bottom of the string of sensors, providing an electrical signal depending on the detection of the chip in its right. 7

The sensors 8 for identifying the color of the chips are placed on the side of the float F1 ... Fn, the opposite of the light source 7, to recognize the color of the chip, 9 respectively the associated denomination according to color. The color information from the sensors 8 is taken over by the microcontroller 9 via a 12C serial communication bus 11.

The electronic module 5 takes over the signals from the optical sensors 6 and the color sensors 13 8 by means of C1 ... Cn comparator type circuits with bridge output.

Depending on the evolution of the voltage taken from sensors 6 and 8 on the inverter input “-” 15 of the comparator C1 ... Cn, the resistance R1 ... Rn placed on the output of the comparator C1 ... Cn is coupled to the positive terminal if the voltage taken from sensor 6 or 8 is less than 17 the reference voltage of the non-inverting input “+” or to the negative terminal if the voltage taken from sensor 6 or 8 is higher than the reference voltage. 19

All the outputs of the comparators C1 ... Cn are connected by means of the output resistor R1 ... Rn to a common potential, thus obtaining at the output of the circuit a linear voltage 21 variable depending on the number of sensors affected by light.

The variable voltage at the output of the circuit is taken by means of a digital analog converter 23 and interpreted by the microcontroller 9. Thus the number of blocked sensors can be determined, respectively the number of chips present in the row. 25

The following is an embodiment of the system according to the invention for monitoring the color chips in the roulette game.27

It is known that in the roulette game, in addition to the F1 float ... Fn, in which there are 1 value chips, there is another type of 2 chips, namely colored ones that are only in formations29 of 20 chips each and are called “ stack ”, (I stack = 20 2 color chips), 2 chips that receive a certain value depending on the name the player wants31 to play.

A roulette wheel has basically 7 colors of 10 stacks each.33

Example: Brown color of 5 / token, 1 brown stack = 100

It is also known that in the game of roulette a way of monitoring the 2 35 color chips is done with the help of the so-called chip collecting machines (Chiping machines „Chipper Champ 2 by TCS John Huxley). These chip collectors contain 37 color sensors. They are mounted on the roulette table in the area dedicated to collecting chips bet by players. 39

This solution is good but very expensive.

An alternative to this monitoring system is the system according to the invention which 41 contains a set of 10 optical sensors 6, one for each stack 13.

A light emitting device in the infrared spectrum will be installed above the card game table.

In order to be able to monitor 2 color chips in less than 20, it is necessary to install a chip monitoring system according to the invention containing 7 rows of optical sensors 6 and 7 rows of color sensors 8, one at a time. for every 47 colors.

The condition is that the string of sensors 6 and 8 contains 20 photoelectric sensors one for each color token, and the size of the string is fixed by 20 chips.

The signals from sensors 6 and 8 for stack detection are taken over by comparator type circuits C1 ... Cn „open collector so the information becomes available in binary format and is applied to the TTL type inputs of the microcontroller 9.

This allows you to monitor the flow and number of colored chips in the roulette game.

The following is an embodiment of the system according to the invention for monitoring the betting boxes of card games.

It is known that in card games there are "box" designs, dedicated to betting. The system, according to the invention, provides a 6 photoelectric sensor for each speaker, which helps to monitor the number of speakers played.

A light emitting device in the infrared spectrum (not shown) will be installed above the card game table. When placing tokens 1 with value on the betting box, the dealer who deals the cards must place the first card offered to the player on the photoelectric sensor 6 in order to be registered in the central server S as the open betting box.

The signals from the sensors 6 for the detection of the betting boxes are taken over by comparator type circuits C1 ... Cn „open collector so the information becomes available in binary format and is applied to the TTL type inputs of the microcontroller 9.

This monitors the number of open / closed speakers on the card game table.

Claims (5)

1. A system for monitoring a game of chips played in a casino consisting of 3 at least one chip tray (F1 ... Fn) each containing 1 ... n rows of value chips (1), 1 ... n rows of colored chips (2) and 1 ... n betting boxes (3) from card games 5, equipped with color sensors (8), characterized in that each of the token trays (F1 . ... Fn) having its own light source (7) 9 consisting of a series of infrared LEDs, one LED for each token, with a wavelength in the visible spectrum, infrared or ultraviolet, depending on the optical sensors 11 used, the color sensors (8) being arranged on the other side of the tray (F1 ... Fn). Photoelectric system according to Claim 1, characterized in that the concave optical guide 13 (4) facilitates the propagation of light from the source (7) and the phenomena of reflection and diffraction.15 Photoelectric system according to Claim 1, characterized in that the electronic module (5) is equipped with optical sensors (8) for counting and identifying the color of the chips17 (2) and with photoelectric sensors (6) for identifying the value of the chips (1) and the value of the betting boxes (3) contains a microcontroller (9) which takes the information from the sensors (6) and / or (8), 19 calculates the balance of the game table and associates it with the dealer present at the game tables, through an application dedicated software, which has the role of storing all the information in a central database (11) to allow both the monitoring of the game table, in real time, and the generation of the necessary reports to the casino management team.23 Photoelectric system according to Claims 1 and 3, characterized in that the microcontroller (9) on each electronic module (5) of each tray (F1 ... Fn) picks up the signals from the photoelectric sensors (6). and / or from color optical sensors (8) by means of comparator-type integrated circuits (C1 ... Cn) with bridge output, perform the data acquisition, 27 as well as their processing and transmission to a central server (S) through a communicator. (10). 29 Photoelectric system according to Claim 4, characterized in that all the comparator outputs (C1 ... Cn) are connected by means of an output (R1 ... Rn) 31 output to a common potential, thus obtaining a linear voltage varying depending on the number of sensors affected by the light, which is taken over by 33 an analog-to-digital converter (12) and interpreted by the microcontroller (9), thus determining the number of blocked sensors and the number of chips present in the row. 35