JPS60500340A - Improved card reader for security systems - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention]

for security systems Improved card reader Background of the invention This application relates to the field of doorway security systems, and in particular for doorway security systems. The invention relates to the field of card reading devices. Doorway security system with magnetic card reader at the door to be controlled systems are known in the prior art. Such systems support multiple readers. with a central controller connected to it, each of which must be controlled. located at a specific door. are not allowed to enter or exit through the door. The person who received the card inserts the magnetic card into the hole in the reader. After that, the magnet on the card The air code is read and data is sent to a controller that authorizes entry. Decide whether to accept or reject the application and keep the door locked to that reader. Begi will either tell you or that door should be unlocked. Problems arise when communication is lost between the remote card reader and the central controller. . J, Unatogi, if all access is denied, people's lives will be in danger. may be exposed to If anyone is authorized to enter and exit, security because there is no record of who is authorized to enter or exit during degraded mode. Barriers are broken, but I don't hesitate. Summary of the invention What is disclosed here is a security system that controls entry and exit through locked doors. (a card reader used in systems), and the security system is It has a central control unit and multiple card readers, each reader controlling a locked door. . The card reading device reads magnetic data stored on cards held by employees. read The card has a system code stored magnetically or otherwise on it. Data and 1. D. It has data. The reader is centrally controlled as soon as communication is possible. Send card data to the device, and the central controller will Reads the signal that authorizes or denies the card reader to unlock the door, etc. Authorize or deny access by sending a message to the device. Improved card readers can sense when communication with the central controller is lost. data can be read from the card without consulting the controller. It is possible to authorize or deny access based on the information provided. It is inside the reader By comparing the data stored in the degraded mode buffer with the data on the card. The stored data is stored in a degraded mode where communication with the central controller is not possible. It shows the people who are authorized to enter and exit at the time. Data in degraded mode buffer The data can be read based on request criteria or determined by the reader or central controller. periodically loaded from the central controller. Communication with central controller is lost In the meantime, the card reader is authorized for later transmission to the central controller. or transaction 1, D, data about each rejected employee from the card. (Series of data input) 1 to 1 in the buffer. “’Qo” and “NoGo”t - Both ranzaxicons are recorded and classified as such by the control device. I am blown away by. Brief description of the drawing FIG. 1 shows a block diagram of a security system in which the improved reading device of the present invention can be used. There is a diagram C. FIG. 2 is a block diagram of the improved reading device. FIG. 3 is a thick diagram of the optical isolator board. Figures 4a and 4b are logic diagrams of the switch and relay board. Figures 5a and 5b are circuit diagrams of the dog △M buffer I boat and power supply abnormality detection circuit. Ru. Figures 6a, 6b and 6c are circuit diagrams of the CPU reader board. Figures 7a and 7b illustrate the transaction buffer and degraded mode buffer circuits. It is a logic diagram. FIG. 8 is a flow diagram regarding the software of the reader, and is a flow diagram of the software of the reader. 1 shows the steps taken to transmit the data in buffer 1 to the control device. FIG. 9 shows lowering mode 1 to the card reader. D. Data downloading FIG. 2 is a diagram of a memory table within the control device used in execution. FIG. 10 is a flow diagram regarding the software of the control device, and shows information to the reading device. Details of the steps taken by the controller in downloading the information. Ru. Figures 11a and 11b are reader software flow diagrams that are centrally controlled. Entry/exit is authorized during degraded mode and super degraded mode when communication with the control device is not possible. transaction data for the transaction at that time. shows the steps taken to store the data. FIG. 12 shows I based on commands from the central controller. D. When downloading data, it is not captured by ultra-low mode reader. FIG. Detailed explanation of one example Figure 1 shows a system diagram of a typical magnetic card reading security system. Ru. The central control unit 20 has a plurality of card reading devices represented by reading devices 22 and 24. connected to the The controller 20 controls each reading device by means of an activation pair and a data pair. The controller is connected to any card in the system. can communicate with a code reader. For example, the controller 20 uses the activation pair 26 and the data bearer 28 to Communicate with 2. The controller 20 drives the reader 22 for the message, Send commands to it by activation pair 26. The data is transmitted via the data bearer 28. The data is then sent from the reading device 22 to the control device 20. A serial format is used on both lines. Typically, the reader 22 is placed at the door where access needs to be controlled. On the other hand, the control device w20 can be installed at a distance from the door. Ru. The structural details of the control device 20 are well known in the prior art; MA from Lasco Electric System Co., Glenzor, California. It is sold as a model named C530/40. Eye for its control device software is also well known and sold by the same company. In operation, reader 22 receives a magnetic card at card hole 32. typical magnetic Details of the air card structure can be found in U.S. Pat. No. 3,717,749 or 3.811. No. 977. Cards with other structures can also be used; magnetic cards The details of the structure are not essential to the invention. Stores encoded data within the card. can be held and converted into an electrical signal so that it can be transmitted over a line. A structure is sufficient. When a card is read in normal operation, the card is read. The button on line 26 When a call signal is received, data from the card is controlled by data line 28. It is transferred to the device 20. The controller 20 processes the data and applies it to the reader 22. Send back the ll　G　OI+ or ゛NOGO゛′] cloak that causes the desired action to occur. J0 If the cloak is "GO", the reading device 22 reads it through the crawler 34. The door lock is unlocked and the green L "[)" is lit. If the command is Even if it is "NOGO", the IJ and reader 22 will light up the red IED, and if necessary Excite the NOQo relay. some selective items

In this embodiment, the owner of the car 1 is prompted to enter a password from a plurality of digits entered via the keypad 1 on the front of the reader 22. If the password and card number 1 are correct, entry and exit will be allowed. Operation when communication between the reading device and the central control device 20 is disabled 1. JL, this (2) low F T-1 to operation, is called. During the lower mode operation, the active L j is read from the reading device reading data from the S, C's υ-. Comparison of the data read from the card and the IC data stored in each reading device In this case, the central controller determines whether to allow or deny access. The specific information for each reader may be different and may vary depending on the reader. The communication between the central control unit and the central control unit is maintained by the central control unit 20 on a normal basis or periodically by the central control unit 20 into each reader. If desired, reader 22 also monitors multiple alarm contacts connected to line 30. can be coupled to a circuit for viewing. When one of the contacts changes state, the reader 22 senses the change and signals the next ball Q controller 20. The controller 20 then emits a pre-programmed message onto the printer 3. More importantly, the controller 20 emits a pre-programmed message onto the printer 3. More importantly, the controller 20 emits a pre-programmed message onto the printer 3. 1. Close the switch by energizing the relay in the reader of 1. The relay can be connected to an emergency device via line 38, which can be connected to an emergency device such as an automatic telephone caller, phone caller, etc. A linker, alarm system, or any other necessary equipment may be installed.Reader 24 is a modified reader of the stomach type and is used to detect the time associated with an hourly employee's dispatch. The reading device 24, which can be used for record keeping, has a display 40, a card hole 42, and 'in' and 'out' buttons 44 and 46. In operation, the employee Insert the card into the power hole 42 and press either the "in" button 44 or the "out" button 4G. At that time, the data on the card and the date and time displayed on the display 40 are stored in the buffer of the reader @ 24. stored in the file. Based on the system code data on the card, the reader 24 grants or denies entry to the hirer. If entry is confirmed by the reader 24, If the door is locked, the green LED will illuminate and the door will be unlocked via line 48. If entry is refused, the reader 24 will illuminate the red LFD on the face plate. Show this by: All approval or rejection decisions are made by the reader 24 on the cart system. done locally based only on the mucode; 1. D. Each tracker like number and date/time Data relating to a transaction is stored in a local buffer of the reader 24. If necessary (ζ6), the reader 24 may include a lower E-reader buffer. and it is 1.1 for those 1+ who are authorized to pass 1- during degraded mode. D, the number can be stored and the reader can grant or deny entry or exit based on the data in this degraded mode buffer during degraded mode. ~Ranzakujiyon's 1゜D.No. The issue and date and time are stored in the transaction buffer. The controller 20 is connected to the reader 24 by an activation bear 50 and a data pair 52. It is. Control layer device 20 balls reader device 24 by sending a ball signal on line 50. Upon receiving the ball signal, the reading device 2/I executes the transaction. data related to one transaction from the transaction buffer and The data is transferred to the control device 20 via the link 2. The controller may then process the data in any manner, including: 1) printing the data out onto the printer 36; Details of the control device 20 can be found in U.S. Pat. No. 4. ．． No. 216,375 and No. 4.218.690. 1. D. Data regarding those authorized to pass during degraded mode is stored in the read device's degraded mode buffer. The operation of the control device when controlling is explained in more detail below. The reader 24 is configured to read the data when the controller is in a different time zone from the reader. Is the time displayed on the display 40 the time held by the control device 20? It can also include means for shifting. Typically, the controller 20 maintains the master time for the system and the reader 24 maintains its own time. Every 15 minutes, the reader 24 queries the time of the controller 20 and updates the reader's log. synchronize the local time with the mask time held in the controller. When the reader 24 is in a different time zone from the controller 20, a group of onoses in the reader 24 The switch is set to indicate the number of minutes of deviation between local reader time and controller time. FIG. 2 shows a block diagram of a card reader used in a security system such as that shown in FIG. There are actually two different types of reader Although there are different types of readers, the core circuitry of each type of reader is the same; The type of reader has additional circuitry that other types do not have. Figure 2 shows the core circuitry and all additional circuitry common to both types of readers. 1 shows a block diagram of the combined functionality of a reader with an element; FIG. The card reading device of FIG. 2 communicates with the control device 20 of FIG. 1 via an isolation board 54. The card reading device of FIG. Isolation board 54 separates the data on enable pair 26 and data bearer 28 from the rest of the card reader's logic circuitry. work to achieve Isolation board 54 passes the signal from enable line 26 to RX data line 56 and the data from the YX data line to data line 28. RX data line 56 is connected within switch and relay board 62 to multiplexer 60. The purpose of Multiplex't-60 is to connect various data channels. 7.63 of the bus 64. A bus 64 is connected between the switch and relay board 62 and the data 2 address and control terminals of a microprocessor CPU 66 on a reader CPU board 67. Address lines AO-A2 from bus 64 are also connected to multiplexer 60. Through these address lines, the CPU 66 Make the Lexer 6o select one of the data channels connected to it and to its data output connected to pin D7. “Then the microprocessor The server 66 can read the data on its selected data channel via the [)7 line 63. In FIG. 2, the data channels shown are the RX data line 56, which carries command and poll signals, and the RX data line 57, which carries data read from the card. Other data channels are used for other functions of the reader and are not directly relevant to the discussion of the present invention. The data transmitted from the card reader to the central controller a20 is input to the driver 70 from the DO line 68 of the data bus 64. Driver 70 connects the AO-A2 address line of data bus 64 to provide addresses from microprocessor 66. It is also connected to the inn. Driver 70 has several addressable outputs. One of them is the TX data line 58. supplied to the driver 70 The address selected causes that driver to provide the signal on Do line 68 to the selected output. let them be fed. To transmit data, the microprocessor 66 data on the Do bus, and put an appropriate address on the address line AO-Δ2 of the bus 64. Write a response. The serial data on line 1- is then provided to data line 58. Central controller 20 receives the data on data line 28 and processes the data. Depending on what the card reader is, it may or may not operate in some manner depending on what the card reader is. Go relay 71 is connected to the door locking device by line 34. Line 34 provides an interruptible current path to control whether the door is locked or unlocked. can be connected to relay contacts or other switching devices to The Go relay is also connected to the driver 70 by a switching line 72. Ru. The switching line controls the state of the Go relay, thereby locking the door. control the state of the location. The switching line connects to the microprocessor via driver 70. The microb[ ] serie 66 is addressable by the Go controller 66 . The state of the relay 70 is controlled. Microprocessor 66 is also connected to card reader coil circuit 74 by bus 64. In a preferred embodiment, card reader coil 74 is It consists of a plurality of coils connected to the address and data lines of wire 64, each of which connects to a plurality of magnetized spots on a card inserted into card hole 42 or 32. They are arranged so that they interact magnetically. Myroku Processor 66 is a car The magnetic spot on the card can be scanned and read to confirm the data. The details of the card reading coil circuit are known in the prior art and are not essential to the invention. Microprocessor 66 is also connected to additional display 40 by bus 64. It is being continued. In the reading device used for time and attendance functions, that is, as a time recorder, it is necessary to insert the card into the reading device 24 when clocking in or leaving the office. It is desirable that the date and time be displayed externally for the convenience of the Ministry of Labor, who are waiting in line for the event. Display 40 may be any conventional display, and the details of its construction are not essential to the invention. Microprocessor 66 is also connected to a random access memory (RAM) board 78. The RAM board 78 has a RAM breadth memory 80. It includes a battery backup system that supports the battery 82 and a power failure detection circuit 84. Power supply failure detection circuit 84 monitors the 12 volt unsmoothed DC voltage drawn from the AC power line, and when the AC line power supply is failed, battery 82 is activated to retain the data stored in RAM 80. is connected to the power supply terminal of the RAM buffer 8o. RAM 80 is selected by microprocessor 66 through the connection of decoder 86 to the address and control lines of bus 64. Microprocessor 66 enables RAM 80. It generates the appropriate address to select RAM 80 and sets it to fnI! By placing 11640 Activate RAM 80 via coder 86. The data written into RAM 80 is then placed on the data line of bus 64. Transaction buffer 88 is connected to microphone [JB1]l? via bus 64. Tree 6 (to 3)) connected. The purpose of the 1-ranzaktion buffer 188 is to store the magnetic 1. D. The task is to load the data from the data and the local time of the syntax into each one. The V-Iknbu Oj2 tree 66 is also connected to the lower mode buffer 189 via the mother gland 64. The low-T mode buffer 89 provides a low T-mode buffer 89 for 1, D, -'7'- evenings for people on the 11th floor who are authorized to enter and leave in accordance with the reduced mode operation when communication is not possible with the central control unit. Sl-74-ru. The control device 20 Lower the data to within 7 >= 89. The COM board 90 is also connected to the marker 1' crop 66 by a bus 64. The purpose of the CCM/COM board 90 is to monitor the status of external devices such as alarm devices or card readers, and to It is to generate data indicating the status of the alarm device for transmission to the central control unit. , CCM/COM board 90 also supports the CCM, COM board board. Data can be received from a central controller that causes the switch to close. This sui The switch is connected to emergency equipment by line 38. The alarm contacts are connected by line 30 to cCMycov board 9o. When the card reader is being used for time and attendance functions as required, the in and 01lt buttons 44 and 64 indicate to the card reader whether the cardholder wants to enter or exit the area. used to tell. , in and 0 ("[buttons 44 and 46 are connected to MUX 60 in the switch and relay board 62 by line 92. The red and green indicator LEDs represented by block 97 are Each is connected to the MIJX 60 by a bus 96. Their 1F[) is used by the microb[1 processor 66] to indicate whether authorization has been granted or denied. is connected by bus 64 to function memory 98 and program memory 100; program memory 10o is connected to microprocessor memory 100; command 4 for the processor 66, and data indicating that the function memory 98 is valid for the processor 6G. Toa. FIG. 3 shows a circuit diagram relating to isolation board 54 of FIG. 2. The data line 28 is connected to the [Rector and Emitter] of the transistor 106 within the optical isolator 102. Light emitting diode of optical isolator 1o-2 108 is cross-connected to TX data line 58. When current is flowing in the TX data line 58, the 1ED 108 is energized and emits light that causes the resistor 106 to assume one of its two switching states. Ru. When LED 108 goes out, the opposite situation is taken. The activation line 26 is connected to the LEDI 12 of the optical isolator 116 via a noise suppression circuit 110. Optical isolator transistor 114 has its collector and emitter connected to RX data line 56. In a preferred embodiment, the light The optical isolator 116 is lvl onsanto M0-2. optical eye Thread 1102 is Mon5anto 4 N33. Details of the circuitry of the switch and relay board 62 are shown in FIGS. 4a and 4b, which are logic diagrams of the board. RX data line 56 is multiplexed. It is connected to the data input 01 of the server 60A. on the isolation board. Unless transistor 114 clamps line 56 to ground potential, the resistor Star 59 supplies +5pol1~ to line 56, ensuring that it is clamped to a logic one level. The other data inputs of multiplexer 60A are connected to other data channels. Connected to Nerhe. For example, card reader coil circuit 74 is connected by line 57 to the DO input of multiplexer 60A. Coil sense signal line 57 carries data from each coil in card reader coil circuit 74, which is addressed by microprocessor 66. Out switch 46 and in switch 44 are connected to D2 and 03 by lines 118 and 120, respectively. Address line 122 of multiplexer 60A is connected to the -A2 address line of bus 64. The output 63 of multiplexer 60A is connected to the D7 data line of bus 64. The microprocessor 66 has the address The address provided on bus line 122 controls which data input is connected to data output 63. Chip select input 126 is connected to address lines in bus 64 of microprocessor 66 via a decoder on the reader's CPU board, discussed in more detail below. Microprocessor 66 can enable multiplexer 60A by writing the appropriate address on the address lines and driving a decoder (not shown) connected to line 26. Multiplexer 60B has its data output connected to D7 data line 63. The power is right. The data inputs of multiplexer 60B are connected to various data channels. connected to the channel. The XO data input is connected by line 128 to a tamper switch (not shown). The switch is arranged to change state when the faceplate of the card reader is removed, producing an alarm message to be transmitted to the controller 20. The x1 data input is connected to a "card in" switch (not shown). The ``cart-in'' switch is arranged to change state when a card is inserted into the card hole. The status of these two switches will be checked periodically. Therefore, the microprocessor 66 detects that tampering has occurred. or whether there is a card in the card hole that should be read. You can let us know what you think. There are three groups of eight switches on the switch and relay board 62. It's true. The time offset group of switches 136 is It consists of eight switches 136 that are used to set a binary number representing the fraction of a time offset at the location. In such a case, where the local card reader is in a different time zone than the central controller 20, switch 136 is set for that number of minutes, thereby separating the card reader's local time from the central controller's time. Become. The second group of switches 138 has several purposes. Switches 1388-0 are used to set the amount of time that the unlock signal on line 34F to the door locking system will keep that door unlocked. Switch 138Δ-D also determines the activation time of No Go relay 166, during which time the red and green LEDs (not shown) in box 97 of FIG. 2 are illuminated. Decide on the time. Switch 138F is used to indicate whether 12-hour or 24-hour format is selected. Switch 138F is used in the controller to enable or disable buffer RAM 80. Switches 138G and H are not used. Switch 171IO is used by the user to set the system code. Ru. The system code is magnetically stored in each cardholder's cart. This is one of the items of data that was created. When making an authorization decision locally without querying the card reader or central processing unit 20, it is determined whether the authorization is granted. It is the system code stored on switches 140A-H that is compared to the system code on the cart holder's card in order to determine the system code stored on switches 140A-H. Switches 136, 138 and 140 are addressed by microprocessor 966 through multiplexers 6'OA and 60B and decoder 140, respectively. possible. Address input 142 of decoder 140 connects to the address line at bus 64. It is continued. The address provided on line 142 is converted at BCD to decimal decoder 140 into a logic O signal on one of the output lines O-6 making up bus 144. Each of the lines connected to busbar 144 is connected to a switch group. connected to one terminal of a plurality of switches in loops 136, 138 and 140. It will be done. When a group address appears on address line 142, one of the outputs on bus 144 goes low, thereby activating that group. The other terminals of each switch are connected to lines 132, 134, 130, 128.146 or is connected through 148 to one of the multiplexer 60B's It is connected to the cathode of a gouioto with a closed anode. All ×0 to ×3 human power is also applied to the −5 volt connected to the main power supply. The line that connects the input of the Xo-X3 is the decoder. one whose switch is closed by a logic O from the controller 140. remains in a logic 1 state unless it is also connected to a group with held. The group of switches connected to the X O - For any particular input of multiplexer 60B, only one switch is connected to both enabled lines. It will be done. The microprocessor 66 thus addresses the address lines on the bus 64. Groups 136, 138 and 140 by changing the address signal. Each switch can be read out individually. The disable-line of multiplexer 60B is grounded by line 15.8, and its disable input is held high by a connection to the +5 volt supply through resistor 160. The disable input is pulled low and takes the D7 output from a high impedance state when signal CSSW is true on line 162. Line 162 is connected to the decoder on the reading device @CP U board 67, and the decoder The controller is connected to the address and control lines of microprocessor 66 in bus 64. It will be done. Data to be transmitted to microprocessor 66 is placed on TX data line 58 by driver 70. Driver 70 also has several other outputs. For example, output line 164 can be connected to an additional No Go relay 166. line 164 is When grounded by driver 70, the +5 volt power supply connected to the other terminal of the coil of No Go relay 166 causes current to flow through the relay coil and to The relay coil is thus activated and the electrical state on line 168 connected to the relay contact changes. In the preferred embodiment, decoder 140 is a Signetic model 74145 TTL decoder and multiplexer 60A is a Texas Instruments model 74145 TTL decoder. This is a 74LS251 type multiplexer manufactured by The driver 70 is an 0MO8 type decoder MC14512 manufactured by Trolla Corporation, and the driver 70 is a NE590 type driver manufactured by Signetic Corporation. Output line 96 from driver 70 is connected to a GOLED (not shown) to activate its LE[) when access is authorized. Output signal from driver 70 In 72 is connected to the terminal of the coil of GO relay 71 . The driver 70 is When grounding line 72, the -5 volt power supply connected to the terminal of the relay will activate the coil, causing one contact in the relay to change the state of line 34h connected to the doorway locking device. Make it. Driver 70 has a data input, DO data pin 1~ on line 68, and an address input on line 172. The at1nos input 172 is connected to the microb 1sey 1s 66 by the 11 wire 64. The address of force C determines which of the outputs of driver 70 is connected to data input 68. In this way, the microphone pin 66 controls the address on line 172 and the data signal lt? on bus C'54. 1. Inject a logical 0 or 1 into any output of the driver 70 by controlling the data on the data line 68 connected to the output. The activation and clearing of the -1 knob is connected to the gate 282 of FIG. 61) and the gate 250 of FIG. 6C by signal lines C3OUT and R5T. Referring to Figures 5a and 51), a circuit diagram of the RA lvl buffer and power failure detection board is shown. The RAM pannoir 80 It has an address line 174 connected to the address line of the microprocessor 66. do. Data input/output 176 is also connected to the data line of microprocessor 66 on bus 64. , write enable line 178 is connected to a control line in bus 64 from microprocessor 66 so that RΔM buffer '80 reads data via data line 176 to a specified address on line 174. control whether it is being read or written. Chip select line 180 is connected to decoder 86 . VMA signal line 184 of decoder 86 connects one input of NOR gate 182 to the VMA control line of microprocessor 66 of FIG. 6b. ad When there is a valid memory address on reply line 174, the VMA error is true. Since the other input to the NOR gate 182 is grounded, the NOR gate 182 acts as an inverter with an output on the false line 186 when there is a ÷7+memory address on the address line 174F. work. Resistor 188 is a positive voltage to VMA human power of goo 1 to 182 Connect the pressure source to hold Goos 1-182 at logic 1 except when VMΔ is false. One input of the NOR gate 190 is connected to the output of the NOR gate 1-182, and the other input is connected to the output of the NOR gate 1-182, and the other input is connected to the output of the NOR gate 1-182. It is possible to determine V~IA on 184. This produces two logic O's at the input of NOR gate 190 and a logic 1 appears on line 194. This logic one is reversed in NOR gate 196 and appears on line 198 as a logic O. If the power supply is defective, the NOR Goo 1-200 sends the power failure detection signal on line 202 from the power failure detection device 84 to the chip selection input of the RAM buffer 80. power line 180. However, unless the power supply is defective, the signal on line 180 indicates whether RAM 80 is selected or not selected. Control squid. Normally, the signal on line 216 from power failure detector 84 is a logic O indicating that there is no power failure. If number 18 on line 198 is logic O Then, RAM 80 is selected. This is because the signal on line 204 is a logic 1. This is because it is inverted by the NOR gate to assert the O8 signal on line 180 at a logic O, thereby enabling RAM buffer 80 to write and read data. The RST signal on line 208 is a logic O upon power-up of the reader, discussed below, but becomes a logic 1 after 1.2 seconds, as discussed with respect to Figure 6b. The NOR gate 210 inverts this signal so that its output line 212, which is connected to one input of the NOROR gate 21, outputs 1.2 seconds after power is turned on. is usually low. The input of NOR gate 214 is connected to the output of comparator 222 in power failure detector 84. Comparator 222 has an inverting input 224 connected to a reference voltage that is approximately 5.3 ports if the power supply is not defective. Line 224 is held at this reference level by the voltage dividing effect of resistors 228 and 226, which ground the +12 volt DC power supply. The non-inverting input 230 of comparator 222 is connected to a reference voltage source of 3,6 volts 1 derived from the battery power supply. This reference voltage is generated by resistor 232, which connects battery 82 (not shown) to ground through a Zener diode 234, which has a breakdown voltage of 3.6 volts. , whose cathode is connected to line 230. Continued. Comparator 222 connects its output to a non-inverting input to provide positive feedback. It has a resistor 236 connected between it and the force. The output on line 216 is a logic O unless the power supply is bad. If the power supply fails, the battery reference voltage on line 230 will exceed the voltage on line 224 and the output on line 216 will rise to a logic one level indicating that the power supply is bad. A logic O on line 212 and a logic 1 on line 216 signal to NOR gate 214. 218-)- to a logic O. This O on line 218 is inverted to a 1 on line 202 by NOR gate 220, causing the output of gate 200 to change to O, and if buffer 80 is in the selected state. , deselects buffer 80. When RAM buffer 80 is deselected, no data can be written into or read from the buffer. The power input 238 of the RA~1 buffer 80 is connected via line 242 to a battery 82 (not shown) through any known switching mechanism 240 during a power failure. Referring to Figures 6a, 6b, and 6c, the reader CPU board circuit A route map is shown. Microprocessor 66 connects data line 240 and It is connected to the functional memory 98 by a dress line 242 . The function memory contains data regarding which optional functions are enabled within the reader. Microprocessor 66 also connects data lines 240 and AO to A4 It is connected to the program memory 100 by a dress line 242 . The activation inputs of memories 100 and 98 are shown in FIG. 6C as decoders 248 and 98, respectively. and 250 to microprocessor address lines 242 and 244 and 250. and 246. Clock 252 is connected to lines 254 and 254, respectively. generates timing signals for the IRQ and NMI inputs on and 256. Black The details of the organization and operation of the block and functional memory and program control are well known to those skilled in the art. It will be selected appropriately. Any mechanism for periodically generating signals on lines 254 and 256 is sufficient for purposes of this invention. Microprocessor 66 executes the instructions stored in program memory 100, and within that program there are several brutines that accomplish various functions. The IRQ and NM1 input result in induction into the following subroutines: For example, IRQ line 254, when asserted true, causes the program control of microprocessor 66 to turn on all of the switches shown here. 7'+'4 to the read routine. Once the NfvlI line 256 is asserted true, the microprocessor 66 is directed to the transmit routine, which communicates with the central controller via the Tx data line 58 and the data line 28. 20. Microprocessor 66 must be reset at the beginning of the program by first receiving power to the circuit. Power on reset circuit 254 is achieve the target. The noninverting input 258 of comparator 256 is connected to a reference voltage defined by a resistive voltage divider consisting of resistors 262 and 264 that ground the power supply. The inverting input 260 is connected to one terminal of a capacitor in an RC circuit consisting of a resistor 266 and a capacitor 268. When power is first applied, the Capacitor 268 acts as an initial short to ground, the voltage on line 258 exceeds the voltage on line 260, and the output of comparator 256 on line 270 becomes Reason 1. Line 270 is connected to the input of NOR gate 272 and is connected to the input of NOR gate 272. The converter 272 operates as an inverter. Resistors 2A4 and 276 hold line 270 in a logic one state except when comparator 256 asserts line 270 low. Acts as a voltage divider for The logic 1 at power-up on line 270 is inverted once at NOR gate 272 and again at NOR gate 278 to become the PONC:IR times signal on line 280. As the voltage on capacitor 268 increases, the values of resistor 266 and capacitor 268 increase. At a time thus determined, the voltage exceeds the voltage on line 258''. this child occurs, the 1 on output line 270 changes to an O, and so does line 280. The first 1 on line 280 is communicated as an O to the reset line 284 of CPU 66 by passing through NOR gate 282 . The other input to NOR gate 282 is line 286 from deadman reset circuit 288. Line 286 is normally used except when a program is present, as explained below. It is always logical 0. At the normal logic O on line 286, the first logic 1 on line 280 is inverted by NOR gate 282, causing microprocessor 66 to start the program. The reset dead man reset circuit 288 operates to reset the microprocessor 66 if a software program is present. Usually, de Tutman reset circuit 288 periodically resets microprocessor 66 unless software provides a 1-trigger signal "D/M Trigger" on line 290. Attempt to If for some reason the gD/M trigger does not occur, program control is lost and the deadman reset circuit resets the program. Reset the program counter to the starting program position. The method by which the detman reset function is achieved is by using two retriggerable monostable By using vibrators 292 and 294. One shot 292 has its clear (RD2) input and B input connected to the +5 volt supply through resistor 296. The Q output on line 298, which has power and is therefore always in a logic one state, is a negative conductor. Normally low until transmission occurs on the D/Ml line 290, the O output line 298 is logic low for a time determined by the values of the capacitor 302 and resistor 300 connected to the external RC circuit terminals. 1 state. However, resistance The pulse time established by resistor 300 and capacitor 302 is longer than the duration of the D/Ml-Rig signal. Therefore, output line 298 does not return to zero after the first trigger pulse. This is because the D/Ml ~ rig signal on line 90 is This is because I keep repeating the steps 1~292. The signals on lines 298 and 280 are connected to the inputs of NOR game i-304. The output line 306 of the NOR gate 304 is the one-shot l-294 clearer. Connected to power. The B input of the non-switch 294 is connected to the 15-pol 1-power supply through a resistor 29G. The six inputs of one-shot 294 are connected by line 308 to one-shot 252 and carry a 600 Hz signal. During the initial power-up period After , the NOR game i-304 has a logic O of t)-C connected to line 280, ``,I,=ji・in29]000D,/''L・1 [HeliCa 1 I:) As long as there is a logic 1 in line 298 jJ, output line 306 B; 80% of human power per 294 units

[・の－■ Make Pete's signal ignored. Ikashinaga 15, Shishi line 290-17) D, ・If the N/1 trigger signal does not occur as planned (), 1, - will indicate some problem with the bu[1 gram actual (j1'''・, the one-shot 292 times out and activates the one-shot 294 to one-shot 1. The tallock signal on line 308 then triggers the one-shot t-294 to output the logic O at input 28-6. 9 to 1, which causes line 284 (from logic 1 to logic O to reset microphone D'7 to reset 66. Referring to FIG. 6C, decoder 86 in FIG. A logic diagram of a decoder circuit forming part of the microprocessor chip 248 is shown. The address bus 242 of the processor 66 is connected to the 12-Al4 line. G1 enable input 310 is the input signal for the rest of the system. It is connected to the 02 output from the microprocessor 66. G2Δ activation power is maintained low because it is connected to the output of inverter 314 which has an input connected to a logic one. , 02 F3 human power is connected to the power-on 3 rear signal []○NCLR on line 280. The A and 13m select inputs of the decoder 250 are connected to the address bus 242, and the C select inputs are connected to the R, Wf, etc. inputs from the microprocessor 66. Is the 02 clock Shinkyu connected? It is connected to the △7 line of the address bus line 242. Both cards 248 and 250 are Model 7415138, one of eight such cards manufactured by Tegilly Instruments. The outputs of the two DAs 248 and 250 are connected to various chip select inputs in the system labeled in FIG. 6C. Write an appropriate address on the address line 2420. By programming, the microphone processor 66 can enable any chips in the system needed for a particular operation. Turning to FIGS. 7a and 7b, a logic diagram of the transaction buffer 88 and eight degraded mode buffer circuits of FIG. 2 is shown. In figure 7b A battery backup circuit 356 in the memory serves to protect the information in the RAM chip shown in FIG. 7b in the event of a power failure. Each of the RAM chips is a Hitachi 6116LP-4CIV10S static RAM. The +5 volt line supply voltage on line 358 normally creates a forward voltage on diode 360, or The +5 volt signal is thus connected to output line 362. However, if the power supply fails, the positive voltage on line 364 from battery 366 exceeds the voltage on line 358, creating an inverse I\\\\\\\\ on diode 360. But long Additionally, diode 368 is forward biased, thereby connecting the battery power supply to line 362 to keep the information in the RAM intact. A series of decoders 3A-372 is connected to 11 lines of address bus 242. These decoders are one of four decoders in the preferred embodiment. It is 74LS139. The outputs 374 to 378 of this data are connected to the six RA to 1A11 top selection inputs in FIG. 7b through a power failure detection circuit 382. It will be done. The 8 activation input of each decoder is connected to the VMA output 1 84 from the microprocessor 66 to read the A11 bit when the decoder is activated. Activate the sea urchin decoder. Decoders 370-372 are enabled by enable signals on lines 379-381 connected to decoder 248 of FIG. 6C. Power failure circuit 382 compares the voltage at contact 386 maintained by the line and the voltage at contact 388 maintained by the battery when the line power, represented by the power supply on line 358, is failed. It is detected by Comparator 390 changes the state of its output 392 when the battery voltage at contact 388 exceeds the line voltage at contact 386. The comparator is in the preferred embodiment It is a National LM311. The chip select signals on lines 373-378 are individually connected to the chip select inputs of the RAM chips of FIG. 7b through OR gates 393-398 of 74LS32. Each chip select input is connected to comparator 390 via OR gates 393-398. If the comparator detects a line power failure, all RAM chips in FIG. 7b are deselected to maintain data integrity. The function and connections of the RAM chip of FIG. 7b will be clear to those skilled in the art. Ma Data from processor 66 is sent to a memory with an address on bus 242. human power and output onto busbar 240 to and from the location. Turning to FIG. 8, a flow diagram of the steps taken to transfer data within transaction baranore 88 to central control unit 20 is shown. Steps in Figure 8 A pulse is taken for each incoming ball signal from the controller 20. The CPU normally operates in a supervisory mode represented by state 441 in FIG. Monitoring includes various subroutines that perform housekeeping and command scanning functions. Jump to Chin. These subroutines are represented by state 443. One function is to determine the presence of a ball signal from controller 20 in FIG. This should be investigated periodically. A poll signal is periodically sent to each card reader in the system via the activation pair 26 that connects that card reader. Bo The check for the presence of a signal is represented by state 447 in FIG. If no balls were received, the CPU returns via path 449 to other housekeeping functions in state 443. If the ball is received, the CPU sends the transaction back to An internal counter is incremented each time a file is stored in the file 88. This operation is represented by block 7151 in FIG. If the count is 0 If so, then CPtJ knows that there is data in transaction buffer 88 that needs to be transmitted to central controller 20. Then, movement to stay 1-4.48 is performed by route 450. If the count is ○, there is no data to transfer, and the CPU returns to other functions. This movement is represented by path 453. In state 448, the CPU determines whether buffer option data has been stored in function memory 98 of FIG. If the feature is present, the CPU retrieves the data associated with one transaction from transaction 88 and sends it to central controller 20. This action is represented by state 454 in FIG. This is accomplished by addressing 1 to 1 in the transaction buffer 88 and reading the data there via the bus 64.The data is then converted to a serial A-mat in the CPU 66, and the Do data is It is sent via bit line 68 to driver 70 of FIG. The driver then places the data on the TX data line 58 and This is sent through optical isolator board 54 onto data line 28 to central controller 20. The CPU then returns via path 456 to the monitoring routine. If the buffer 7 option is not present, cpu66 is routed via path 458. and moves to state 460, where it checks for the presence of a card in the card hole. Check. If there is a card in the card reader, the card data will be read by the CPU 66. is converted to serial format and sent to central controller 20. This station is represented by block 462. Control then returns to supervision. If there is no card in the reader, the CPU moves to state 464 via path 465 to determine if there are any pending time requests. A card reader with time and attendance functionality maintains local time and periodically requests time from the central controller to synchronize the local time to the central controller time. too If there is a pending time request, the card reader asks the central controller 200 hours as shown and monitors via route 468. Return to vision. If there are no pending time requests, the CPU confirms the ball by state 470. and returns via path 472 to the monitoring routine. Referring to FIG. 9, a memory table used by the central controller in downloading ID data to a reader for use in ultra-reduced mode. A symbolic diagram of Le is shown. Readers 22 and 24 can request a download when they are first turned on. This is because they do not have any ID data stored in their degraded mode buffers. The central controller 20 also uses a suitable readout device periodically, randomly, or whenever the data in the controller's memory table is changed by the user. You can download degraded mode data to your location. The downloading operation will be explained with reference to FIG. 9 and FIG. 10 together. FIG. 10 shows the algorithm for the software in the controller 20, which is used by the controller to download the ID data to the degraded mode reader. details of the steps involved. All readers in the system are in degraded mode. It does not need to be a collecting device. The reader to be in degraded mode is designated by the user by making an entry in the ultra-degraded mode memory table 7'OO. Each reader in the system has an entry in the SDM memory table 700. reader entry The file consists of 1 byte of data, of which 2 bits specify the conditions of the reader. the rest are used to determine if the particular reader should function in degraded mode. used for other purposes, including specifying whether The first bit 704 in the table entry for reader number OOO is used to signal whether the reader has a pending download request. Pending download dates at any particular time All readers in the system that have a 700 has a tc first pill set in the reader entry in the first pill 700. Each download request 1- signals that the low mode buffer 89 in the requesting reader is full or is in low mode. Individuals are processed individually until the ID numbers of employees authorized to enter the controlled area are exhausted. one particular reading After the download request has been completely processed by the reader, the controller clears the first bit for the reader entry in table 700, eg, bit 704 for reader @000. The control device is responsible for all downloads. This process continues until the request is completely processed. Referring to FIG. 10, receiving a download request from reader XXX is represented by block 708. If the controller initiates a downloading operation, it sends a message to the reader instructing it to make a download request. On the other hand, the download request The data is sent to the control device by the reader XXX. Is the control device the reader XXX? When it senses a download request from the Check low excess mode memory table 700 to determine if the If it is not so designated, the controller sends a termination message to the reader XXX indicating that there is no downloading operation, represented by block 712. If reader XXX is designated as a super degraded mode reader, the controller examines the reader XXX column in reader qualification memory table 714 of FIG. De Group 714 contains a column of entries for each reader in the system. In that system, each employee is assigned a specific ID number and a specific status number. It is being used. The status number indicates which areas controlled by the system the employee has access to. The purpose of reader qualification memory table 714 is to relate readers within each status group. However, Therefore, table 714 contains entries for each reader/status number combination. Regarding ri, it takes the form of ma[~rikusu]. The numbers for each controller/status number combination are time zone numbers. The time zone number for each combination is provided for access to the time zone table (not shown). The table is used to determine which persons with the given status number are authorized to enter and exit the location controlled by the given reading device. indicates whether the If the time zone number for a particular combination is O, then the given Persons with a given status number will never be allowed to enter a location controlled by their given reader. Any reading device/status number combination with a non-zero time zone number is a valid combination for ultra-low mode. That is, checking of the time zone table is not performed in ultra-reduction mode. Te All IDs in the status group with time entries other than O in table 714 are sent to the reader. These people are the ones who read their cards. Entry is permitted even during ultra-reduced mode operation, regardless of the time of entry into the hole. This is specified by the cardholder depending on the time of day. This differs from normal operation, which can only be entered at certain times. After central controller 20 examines reader qualification memory table 714 for reader XXX to determine all status numbers that have a time entry that is not O. , the control device identifies which employees are in the group with those status numbers. It is necessary to judge whether To do this, controller 20 consults identification number memory table 716 of FIG. Table 716 is the system It has entries for all employees who are allowed to come and go. Each en Entry 718 representing a bird has an ID number and a status number. ID number The number identifies that particular employee, and the status number indicates the areas to which that person can enter and exit. The daples 716 are arranged in order of increasing ID number. Ru. Central control processing download requests from reader XXX Control device 20 augments its identification number memory table 716 to find all ID8s that have a status number that corresponds to the status number found when table 714 is examined for that reader XXX. the order in which you Can. Locating all authorized school status numbers in table 714 is represented by step 720 in FIG. To the reader XXX With regard to increasing the position of all ID numbers within each recognized status group. The step of locating in order is represented by step 722 in FIG. During the process of collecting ID numbers for downloading to the reader XXX, the control unit 20 records the "'in process'" entry for the reader XXX entry corresponding to bit 706 for the reader OOO in the table 700. Set bit to After being collected, controller 20 reads the readings in ultra-low mode memory table 700. Bit 704 of the ``Download Request'' for the reader XXX entry is transmitted to that reader XXX for storage in the ``in process'' buffer. These steps are represented by blocks 724 and 726. Thereafter, the control device 2o waits for the next download from the reader. Referring to FIG. 11, a flow diagram of the steps taken by the reader when processing card data in ultra-reduced mode is shown. For illustrative purposes, each reader in the system can be operated in either ``Low Drop Top Mode'' or ``Ultra Drop'' Mode, as appropriate. It can also function in both cases. In either case, communication with the central controller 20 is not possible, but entry/exit permission decision transactions 1 hege operation (or each mode They differ in terms of In the "lowering mode", the reading device's speed in Figure 4B If the system card on the card is programmed by the user on the Compare mucodes! Get out of the way. If necessary, the reader records the ID number and []-cal time in the transaction buffer for the one-run transaction for which authorization has been granted, and then "Go" the entry. Make it a run reaction and mark it with -C. In the ``Ultra-low'' mode, the reader is connected to the switch for cars 1 to 10 of the system. 7. Check the ID data at 7 against the data in the lowered mode buffer j downloaded from the control device. The reader is 00” or records all 1 to 1 runs of "NOGO" in the 1-run buffer and marks them as such. Block 800 in FIG. 11 represents a monitoring routine.1. Some of the batteries are The ground block 802 performs routine housekeeping checks. (if the reader is running one of its foreground processing routines to handle a condition discovered by the CPU while processing) It performs the function that the card reader performs when the card reader is not present. Part of the normal monitoring routine is to check for periodically absent poll signals from the central controller. This chi The check is shown in block 804, denoted by Block 806 represents normal command processing performed by the reader during normal communication with the central controller. These processes include, for example, reading the card in the hole, sending the card data to the control device for determining entry/exit permission, and receiving the message from the controller to approve or deny entry/exit. such as authorizing or denying access. The reading device 16. Ti, while the number 18 is lost, the ID number of all employees who are allowed to be second-duty must be loaded into their lowering. This town o-ding must not occur. (There are at least two times when you don't learn. One is when you power up.) The second is when there is a complete change in the information in the central control unit related to the super-lowering mode. -1[1tsuk80 8.810 and 812 represent the power-up lower Z low)'' ink, -b[]tsuk808 is lowered and the first one after power-up is lowered. 9 represents a decision as to whether the If a drop condition is discovered. The reader CPU determines whether ultra-reduced mode operation is present in the functional memory represented by block 810. If the reader is powered off A determination is made as to whether the UP state or ultra-reduced mode option exists in the functional memory represented by block 810. If the reader is not powered up or a super degraded mode option is not present, the control Return to Chin800. If the reader's CPU is in a power-up state and the ultra-reduced mode option exists. If detected, the reader will request a download from the control device, and the downloaded ID data will be stored in the ultra-low mode entry/exit authorization buffer 78 shown in Figure 2. Store data. This is represented by block 812. After the drop loading is complete, control returns to monitoring. If the reader's monitoring routine does not detect a poll within the last 30 seconds, the reader The processor's CPU enters a degraded mode represented by path 814 and subsequent states. The reader first inserts a cap into the reader hole, as represented by state 816. It must be determined whether the code exists or not. If no card is present, control returns to the monitor routine as represented by path 818. If a card is present in the reader, the reader's CPU reads the card and then returns the card to determine whether the ultra-reduced mode opsicon is enabled, as represented by state 820. Check function memory 98. If not, the program moves to day 1-822 where the reader CPU checks function PROM 98 to determine if the degraded mode option is enabled. If it is not valid, the program control as represented by path 824 Control returns to the monitoring routine 800. If the reduced mode option is enabled, as determined by state 822, then the reader's CP 1. J compares the system code data on the card in the hole with the system code written to the switch on the switch and relay board 62 represented by state 826. If a match does not exist, program control is transferred to state 828 where the red LED on the front panel of the reader is turned on at a fixed time point. It is lit. Some readers have a valid 'NoGo' option. The controller CPU checks function memory 98 to determine if the 'NOGO' option is valid, as represented by state 830. If it is not, control is transferred to the monitor. If it is valid, the reader CPU energizes the "NOGO" relay for a period of time set by a switch on switch and relay board 62, as represented by state 832.N OG.Relays can be used to sound alarms or control other functions. Ru. Control is then passed back to the monitor. Referring again to state 826, if a match is found in the system code, the reader will energize the "GO" relay as represented by state 834 and the green! , lights up the ED. If the buffer option for degraded mode is enabled, as determined by state 836, then the reader is in the transaction buffer? The card reader's CPU stores the card's ID number and local time in the Later, when the contents of the transaction buffer are transmitted to the central controller, the 'Go' transaction is printed out in one color, while the 'Go' transaction is marked as The "No Go" l-ranzation can be printed out in different colors. This action of recording and marking transaction records is represented by stay 1-838. Control is then returned to the monitor 800. Returning to state 820 of FIG. 11, if the functional PROM 98 reader CPU chip If the check indicates that super degraded mode is enabled, the super degraded mode entry/exit authorization buffer must be checked to determine if it is full. This check is represented by state 840. If it is, the card in the hole is ignored, as represented by state 842. If the ultra-reduced mode entry/exit authorization buffer is not full, program control is transferred to steps 1-844. Therefore, the reader CP tJ has -IDEC option. Function PROL 98 is checked to determine if an option exists. If it exists, the control will move it to station h 846 where it will be read and read. The CPU at determine whether the If the IDEC option is not enabled, the booter error 846 is skipped and the bootable error is executed as represented by path 848. enters stock states 850 and 852. If the IDEC password consisting of several digits entered on the reader's keyboard 85/l is not properly entered, the reader enters steps 1-856. State 856 takes the ID number from the rejected card and its date and time for that transaction and writes it as a τ'NoGo''l-run transaction. 3 represents reader CPU operations to mark a bird. 1-Ranzaku Jonbag Transactions in the file 88 are marked either 1QO11 or il NoQo, and they are printed out in different colors or distinguished by the central controller. If the IDEC option is present and the IDEC password is appropriate, If entered, the reader@CPU indicates that a system code match exists between the card data and the switch. State 850 is entered to determine whether 7J1 is present. If there is no match If so, state 856 is entered. If a match exists, the reader CPU State 852 is entered to determine if a match exists for the code. ID code In order to adapt the code, the reader cPU will The ID data in the ultra-low mode entry/exit authorization buffer 89 downloaded from the controller Compare the ID data from the data and the card. If a match exists with any ID in buffer 89, the reader CPU enters step 1-858 to store the transaction. The state 858 stores the ID number and local time from the card in the migration buffer 88. ~ represents the step of marking the record as a 'Go' transaction. The reader CPU then enters state 860 where the GO relay is energized and the green LED is illuminated. Control returns to the monitor routine 800. After the transaction buffer is loaded and communication with the central controller is restored, the reader uses the algorithm of FIG. The data is transmitted to the central controller one transaction at a time. Referring to FIG. 12, the central controller downloads the ID data into the ultra-low mode buffer. the steps taken by the reader when you request it to be scanned. A raw diagram is shown. As usual, the reader CPU receives commands from the controller as part of its routine, as represented by state 862. Functioning within the monitoring routine 800 when a query is made as to whether the If a command is not received, the remaining tasks of the monitor routine continue as represented by path 864. If a command has been received, the reader CPU enters state 866 and It then determines from the function PROM 98 whether the ultra-reduced mode option is present. If it does not exist, program control will and returns to the monitoring routine 800 to determine if there is anything to be done. be done. If the ultra-reduced mode option is present, the reader CPU enters state 868. In this stage, the reader receives the commands received from the central controller. Determine whether the command was an ID dump command and delete the ID dump command. indicates that the controller wishes to download ID information from its memory table. If it is not such a command, the reader The location returns to the monitoring routine 800 to determine what to do. If the command is an ID dump command, the reader enters state 870 where it requests a download from the CP LJ. The reader then enters state 872 where it receives information from the controller. The ID records that are stored are stored in eight ultra-degraded mode buffers. If each ID card comes in, the reader is The CPU stores it and checks if the ultra-low mode buffer 89 is full. State 874 is entered to determine whether. If it is not satisfied, the reader requests another ID record, as represented by stay 1-876. The controller 20 may not have any more IDs to send. Since the reader CPU does not have any more IDs to send, it enters state 878 to determine if the controller has sent a message indicating that it has no more IDs to send. If the controller sends such a message, control is returned to the monitor routine 800. However, if such a message is not sent If so, program control is returned to stage [-872] to store the next incoming ID record. Returning to state 874, if the ultra-low F mode buffer 89 is filled with the last received ID record, If the reader CPU discovers that it is, it enters step 1-880, where the reader transmits a "I'm full" message to the controller, informing it that it can no longer accept any more ID records. .Control then returns to the monitoring routine. Ru. Below, as an appendix, are provided the reader rough 1-ware purpose codes for implementing the ultra-reduced mode functions described herein. Although the invention has been described in terms of preferred embodiments, it is intended that any modifications may be made which accomplish similar functions in similar means using similar devices. 00840F 810 A 2716810B 2717 C644D7 LIS ED CRY:48045 C643D744 C642D74397427C 00303986CR501/SDM OPr Engineering (1) 490 FF 972E 39000036F 42098CFF FF 26F87F4A00030 7F 002E 39 OA 0704010F OF OF OF OB 0 94CO84027A 004F 2626 BD 8626 BD 872D BD 875B 5UPERDEGRN)ED4DOBD 865. CBD 86 As BD 89 9F 8D 13 BD 858A 8D 2E 0 PTION500 QC86FF 97203996 B72A 037C00 2039962D510262D 962927162A 204327099 6 B62B 2086520 FF 97293996 B62B 297F 0029394F 972896530 B62A QC860197293 996B62B 047F 0029395509486 FE 972939 C682C40127129600270 F5602A IA 432717 B648072A IA C6FF D700335F570 D728 B 648072B OD C601D70039 B648072A580045 F D70039 C6FE D70039968284 QC274C590 B640162B 47 CE 4000 C607B7401A FF″40 185CO01A6002A B6 FE 40186C00QC562001 54 5FO2733 96C22) 32F 86 FF 97213996 C 22A 21966EO538771876D 878D 878887929 62D 2620966F022810126 Eng081 O27 QC966 1261396B62A7001F 86 yen-9 72B 7F 00867F 0087 C6FF D724397107F 00867F 0087 C6 "Yen" D724 α000E 7E 87 F77AODF OE DF 10 9680842027037F 008439 α0O8300119B740 40816026237F 4040 B6403F 8B RUM No.: SII'l OPI Go (1) F2O00000000000000000000 000000000000I condolence o oo oo oo oo oo oo oo oo oo oo oo oo oo oo oo oo o. FIG, 1 i+- FIG, ua FIG, 5b FIG, 6b FIG, 6c FIG, ryo a country mouth

Claims (1)

[Claims] 1. A security system for controlling people's access to an area, To control access to and from the area and to read data stored on the card. In order to ensure that the data is stored in the reader, no one is authorized to enter or exit the area. a card reader for comparison with data regarding whether the card is The card reader must be able to confirm if the card data is stored in relation to the authorized person. If it matches the data, it authorizes access to the area, The system includes a central controller, which connects the card reader and the central controller. Who is authorized to enter and exit the area when communication with the device is not possible? When it is possible to store related ID data and further communicate with the card reading device. A security system characterized in that the data is communicated to the card reading device at Mu. 2. When communication with the central control unit exists, the central control unit issues access permission. communicating the data read from the card to the central controller in a manner determinable; means for making the entry/exit permission decision in the reading device; and to send a message to the card reader regarding whether or not to authorize entry/exit. Claim 1, characterized in that the central control unit includes means for: Built-in security system. 3. A plurality of card reading devices are included, and the central control device is connected to the card reading devices. which of said reading devices authorizes entry and exit when communication is lost. A first means of storing data about who is being hired and which employees are Stores data about whether each card reader is authorized to enter or leave the location a second means for receiving a request from the reader for downloading ID data; and when the requesting reader is in degraded mode, the first Determine whether you are authorized to enter or leave by examining your means. and by the requesting reader when in degraded mode. View identity data on all people authorized to enter and exit controlled areas. the second means for storing the data; and the data for storage. and third means for sending the requesting reading device to the requesting reading device. An apparatus according to claim 1 or 2, characterized in that: 4. The reading device is connected to the central controller after the initial power-up of the reading device. Contains a means for requesting downloading of an ID number from 2. A device according to claim 1, characterized in that: 5. The card reading device reads a card that confirms the organization to which the card holder belongs. Reads storage system code data and ID data that confirms each specific individual 2. A device according to claim 1, characterized in that: 6. The card reading device reads only the system code card data as necessary. or by both the system code and the ID data on the card. Claim 5, characterized in that it includes means for authorizing or denying access. Apparatus described in section. 7. ID data for all persons admitted during degraded mode. further comprising means for storing data for later communication with said central controller. 7. A device according to claim 6, characterized in that it comprises: 8. Contains a means for storing when each person is admitted. 8. The device of claim 7, characterized in that: 9. Regarding each person who is admitted or denied access in J3 in degraded mode operation. The data record containing the ID data to be sent to the center later when communication is restored. A claim characterized in that it includes means for accessing the stream for transmission to a control device. The device according to item 6. 10. The data record includes the run sequence from 1 to 1 of the time and enters and exits. ``GO'' 1 - ``GO'' who was admitted or refused entry or exit ``N'' Claim No. 1 characterized in that the transaction is marked as 0GO°' The device according to item 9. 11. The card reader (including the upper keyboard 3, and the system code all of the cards and the ID data of the cart and the key by the cardholder. Includes means for granting or denying access based on a secret word entered on the board. 6. The device according to claim 5, characterized in that: 12. A security system with one central control unit and multiple card readers. the device means, said card reading device means reading data stored on the card; and when communication with the central controller is possible, the central controller or to authorize entry or exit when communication with said central controller is unavailable. a card reader means to locally determine whether to reject the card. connected to said central control unit in order to compare the card data with the received data. furthermore, said card reader means is incapable of communicating with said central controller. who are then authorized to enter specific areas controlled by their reader means; storing data from the central controller regarding whether the The system further includes communication between the central controller and the car 1 to reader means. 1 heranzakushi for each person who was granted or refused access when the person was unable to believe. In order to scan the ID data and date and time related to storage means within the device means; the plurality of card reading device means when communication with the card reading device means is possible; In order to receive card data transmitted from access to and from said card reader means for determining whether to accept or deny the card reader. the card reader who sent the approved or rejected card data; means in said central control unit for transmitting messages back to the determining when the ID reader means is requesting download of ID data; and communication between said card reader means and said central controller is lost. When in degraded mode, the requesting card reader means that no one can enter or exit the system. and to determine if the card is authorized to be read during degraded mode. identification data for each person authorized to enter or leave the area controlled by the control device means; the card reader for locating the ID data and for storage of the ID data. means in said central control unit for transmitting said data to disability system. 13. Those who operate security systems including card reading devices and central control devices The law is reading a card and retrieving data from said card; sensing whether communication between the central controller and the card reader is possible; step and If communication with the central control device is possible, the card data is sent to the central control device. and the central control of whether access should be granted or denied. Steps to determine in the device and whether access should be granted or denied sending a message from the central controller to the reading device indicating the by the card reader based on the message from the central controller. authorizing or denying access to the controlled area; When communication with the central controller is disabled, the card is removed by the central controller. Compare the data scanned into the reading device with the card data, and perform the comparison. security characterized in that it includes the step of authorizing or denying access based on How to make the system work. 14. In a prize guarantee system that has a central control unit and a card reader, A method for operating a card reading device, the method comprising: To those who are authorized to enter or leave the premises when communication with said central control unit is lost. loading ID data related to the data into a buffer; sensing when communication with the central controller is lost; System code data that confirms the cardholder's organization and ID code that confirms each person. reading card data including card data; said system card data to a first set stored in said card reader. the central controller while communication is maintained; a step of comparing said ID code data with a second set of data loaded from Up... The ID data from the card is stored in the buffer of the card reading device. If the system code or the ID:ml-code is If the record does not match the stored data in the The system code and the ■D code are marked as “GO” the record if it matches the data stored in the card reader. Security characterized by being marked as unauthorized and allowed to enter or exit How to disable the card reader in the system. 15. Operate a security system that has a card reader and central control unit A method, Entry/exit is not permitted during degraded mode when communication with the central controller is lost. It is necessary that the card reader be loaded with ID data relating to the people being identified. a step of sensing when it is needed; When in degraded mode, the reader determines which persons are authorized to enter and exit. Steps to determine and to determine if the card reader is running the risk in degraded mode. data on civilians who are allowed access to areas controlled by - locating and to the requesting card reader for storage; transmitting the ID data, the ID data being transmitted to the central controller. the card reader when permitting or denying access when communication with the The security system according to claim 14, characterized in that the security system is used by How to make the system work. 16. Operate a security system with a central control unit and multiple card reading devices A method that allows access to and from areas controlled by each card reader. a step of storing ID data of all the people being identified in the central control unit; and relating to a particular card reader when communication with said card reader is possible; transmitting the ID data to the card reader; When communication between the card reading device and the central control device is disabled, the central control device local to a specific card reader without requiring any communication with the control device. the cardholder for the purpose of making a decision to grant or deny access to the cardholder. Compare the data stored in the card reader with the data read from the card. A method of operating a security system, comprising the steps of: 17. Entry/exit is authorized or denied when communication with the central control unit is unavailable. Whether or not the ID data and each transaction are stored in the card reader - and then sends the traffic to the central controller when communication is restored. Claim 1 comprising the step of transmitting transaction data. The method according to item 16.