JP3760466B2 - Card system management device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a card system management apparatus in a prepaid card system for purchasing goods, services, etc. using a prepaid card.
[0002]
[Problems to be solved by the invention]
In recent years, systems for purchasing goods and services using telephone cards, orange cards (trademarks), gas stations, rental businesses, cards for vending machines in restaurants, and the like have become widespread. These cards are purchased by the user in advance by paying a fee, and are therefore called prepaid cards.
[0003]
FIG. 9 shows a configuration diagram of a card system management apparatus in a prepaid card system for a conventional pay TV. This apparatus comprises a card reading / writing means 4 for reading or writing the remaining frequency stored in the prepaid card 2, a CPU 6 as a control means, a ROM 8 as a storage means incorporating a control program, and operating states of the subordinate televisions. Device operation detecting means 10 for detecting the above, a timer means 12 as a timer, a display unit 14 as a display means, and a remote control output unit 15 for TV control. The CPU 6 is stored in the ROM 8. Operates according to the program.
[0004]
When the prepaid card 2 is inserted into the card reading / writing means 4, the CPU 6 reads the remaining number stored in the prepaid card 2. Next, according to the output from the device operation detecting means 10, it is determined whether or not the television is operating. That is, the device operation detecting means 10 determines whether or not the TV is operating depending on whether or not the load current of the TV is equal to or less than the determination reference value. If the TV is operating, the CPU 6 follows the output of the time measuring means 12. The predetermined frequency is subtracted from the read remaining frequency. At the same time, the current remaining number is displayed on the display unit 14.
[0005]
Thereafter, when the user stops using the television and the operation is stopped, the CPU 6 writes the current remaining number from the card reading / writing means 4 to the card 2. And in order to return the card | curd 2 to a user, the card | curd 2 is discharged | emitted. If the current remaining number becomes 0 while the television is used, the CPU 6 transmits a power-off signal from the remote control output unit 15 to the television to forcibly stop the operation of the television. As described above, a prepaid card system allows a pay TV to be watched without preparing cash each time it is used.
[0006]
A further improvement of such a prepaid card system is a card system management apparatus proposed in Japanese Patent No. 2591689. The device operation detection means here captures the load current value of each device 6 times at a sampling interval of 1/256 seconds and stores each, and when the 6 samplings are finished, the average value of the captured load current value is obtained. Calculated by the CPU. Such sampling of 6 times and calculation of the average value are performed at predetermined time intervals (for example, 1 second). And the device is not used (unused, discontinued) only when the average value of the calculated load current is in the state of 0 twice in succession and the sampling value has never increased out of 6 times. Or, it is determined that the device is being used.
[0007]
By making the determination as described above, as shown in FIG. 10, there is no possibility of erroneous detection even for a device whose load current continuously changes. That is, even if the sampling average value of the load current temporarily becomes zero, the sampling average value of the load current is not zero at the next time point, and it can be determined that the load is operating.
[0008]
However, in the card system management apparatus proposed in the above-mentioned Japanese Patent No. 2591689, there are concerns about the following problems. For example, a load such as a TV has a built-in power supply circuit that rectifies a commercial AC power supply as input power to obtain DC power. However, a load of a capacitor input type in which a smoothing capacitor is inserted inside such a power supply circuit. Even if the load voltage is sinusoidal, the load current flows only during the charging period of the smoothing capacitor and becomes a pulse. Therefore, after actually converting the original load current to the detection voltage, the detection voltage is integrated. It is necessary to determine whether or not the load is operating based on the potential.
[0009]
However, even if the power of the television is turned off, current is consumed internally to preheat the heater of the picture tube (CRT), so the sampling average value of the detection voltage waveform-shaped by the integration circuit is continuously 0. Never become. Moreover, some televisions have built-in video, for example, and a standby current flows to some extent even when the power is turned off. For this reason, whether the sampled load current value continues for a predetermined number of times or more and is equal to or less than the judgment reference value and determines whether the power of the TV as a load is on or off is a constant of the element according to the load. If the judgment reference value is not changed, for example, by changing the power supply, the device operation detection means may be erroneously determined to be on even though the power is actually off. Can not do it.
[0010]
Therefore, an object of the present invention is to provide a card system management apparatus that can accurately determine whether or not a load is in use without sampling the load current or load voltage and determining the value thereof. .
[0011]
[Means for Solving the Problems]
The card system management device of the present invention determines whether or not a load to which an AC load voltage is applied is detected by the device operation detection means, and if the load is operating, reads it from a rewritable card according to the output of the timing means. In the card system management apparatus for updating the remaining frequency, the device operation detecting means includes load current detecting means for outputting a detection signal whose pulse width changes according to the magnitude of the load current flowing into the load. Whether or not the load operates is determined according to the pulse width of the signal.
[0012]
In this case, when the load operates and is in an energized state, a large amount of load current flows into the load. Therefore, a detection signal having a pulse width corresponding to the load current is output from the load current detecting means. On the other hand, when the load is not operating, for example, in a standby state, the load current is reduced by the amount corresponding to the standby current, so the pulse width of the detection signal output from the load current detection means is narrower than in the energized state. Therefore, even if it is a load with a large standby current, if it is determined whether the pulse width of the detection signal has reached a predetermined value or more, it is not necessary to sample the load current or load voltage and determine the value. It is possible to accurately determine whether the load is in use.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a card system management apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 1 shows a functional configuration diagram of a card system management apparatus 1 for a pay TV installed in a hotel or a hospital. Reference numeral 2 denotes a rewritable prepaid card. The frequency is read by the card reading / writing means 4 based on a command from the reading command means 20. Reference numeral 24 denotes a remaining frequency storage means for storing the read remaining frequency. The device operation detection means 26 detects the presence or absence of the dependent load, that is, the operation of the television 34. When the apparatus operation detecting means 26 determines that the television 34 is operating, the remaining frequency update means 30 is based on the time output from the time measuring means 32 and the frequency subtraction coefficient of the television 34, and the remaining frequency storage means 24. Update the remaining frequency of. When the write command means 22 issues a write command at a predetermined timing, the remaining frequency stored in the remaining frequency storage 24 is written to the card 2.
[0014]
FIG. 2 shows a hardware configuration of the card system management apparatus 1 according to an embodiment of the present invention. In the figure, 35A and 35B are a pair of input terminals connected to a commercial AC power supply (not shown) of AC100V, 36A and 36B are output terminals as outlets leading to the television 34, one input terminal 35A and output terminal 36A. The load current detection circuit 38 constituting the device operation detecting means 26 is inserted and connected between the power lines 37A connecting the two and the other input terminal 35B and the output terminal 36B are directly connected by another power line 37B. That is, the AC input voltage from the AC power supply is supplied as it is to the television 34 via the load current detection circuit 38. Reference numerals 39A and 39B denote connection terminals that lead from the AC power supply to the power supply circuit 40. The AC input voltage is converted into a DC voltage by the power supply circuit 40, and is supplied to each part of the card system management apparatus 1 as an operating voltage.
[0015]
Here, the configuration of the load current detection circuit 38 will be described in more detail. R1 is an energization current detection resistor that generates a voltage corresponding to a pulsed energization current flowing through the power supply line 37A. The energization current detection resistor R1 here includes a fuse 41 for overcurrent protection, but this is not essential. Reference numeral 42 denotes a limiter circuit that limits the amplitude of the pulse voltage generated between both ends of the detection resistor R1, which specifically includes four rectifying elements (diodes) D1 to D4, D5 connected in series in the same direction. To D8 are connected in parallel between both ends of the detection resistor R1. Here, four diodes D1 to D4 and D5 to D8 having the same characteristics are connected in series, but the number is not particularly limited as long as a desired limit level is obtained.
[0016]
43, when a pulse voltage generated across the detection resistor R1 is equal to or higher than the first threshold value or equal to or lower than the second threshold value, an L (low) level detection signal is input to the input port I1 of the CPU 52 described later. A detection signal output circuit to be supplied, which has one end of a current limiting resistor R2 connected to one end of the detection resistor R1, and a pair of photocouplers between the other end of the resistor R2 and the other end of the detection resistor R1. It is configured by connecting CP1 and CP2 in parallel. As is well known, the photocouplers CP1 and CP2 are configured by combining light emitting diodes 44A and 44B as light emitting elements and phototransistors 45A and 45B as light receiving elements, respectively. Are connected in parallel. The collectors of the phototransistors 45A and 45B are connected to the operating voltage line of the power supply circuit 40 via the resistor R3, and the emitters of the phototransistors 45A and 45B are connected to the ground line of the power supply circuit 40. The As a result, when the voltage at one end rises above the first threshold with the other end of the detection resistor R1 as a reference, a current flows through the light emitting diode 44A of one photocoupler CP1 to emit light, and the phototransistor 45A is turned on and detected. The signal goes from H (high) level to low level. Further, when the voltage at one end falls below the second threshold with the other end of the detection resistor R1 as a reference, current flows through the light emitting diode 44B of the other photocoupler CP2 to emit light, and the phototransistor 45B is turned on. Similarly, the detection signal is changed from H level to low level.
[0017]
The CPU 52, which is a control means, starts timing when the detection signal from the detection signal output circuit 43 changes from H level to L level, and ends timing when the detection signal returns from L level to H level. If the measured time is equal to or greater than a predetermined value, it is determined that the television 34 is energized. If the measured time is less than the predetermined value, it is determined that the television 34 is not energized. That is, the device operation detection means 26 here detects a pulsed load current flowing in the television 34 which is a capacitor input type load as a voltage generated between both ends of the resistor R1, and increases or decreases the voltage pulse width. Accordingly, it is configured to determine whether the television 34 is energized (ON) or not energized (OFF). In this way, instead of sampling the load current value and load voltage value whose waveform has been shaped by the integration circuit, the presence or absence of operation of the television 34 is determined according to the time of the voltage pulse width corresponding to the load current value. The CPU 52 takes in the detection signal from the detection signal output circuit 43 from the input port I1 without having to bother integrating the integration circuit or considering the sampling time, so that it can know exactly whether the television 34 is in use or not. be able to.
[0018]
A RAM 64, a timer 66, a display circuit 68, a remote control light receiving unit 70, a read / write circuit 72, and a card transport unit 74 are connected to the CPU 52 via a bus line (control bus and data bus) 62. The RAM 64 stores programs such as frequency subtraction. The RAM 64 is backed up and retains its contents even when the AC power is turned off. Among them, the remote control light receiving unit 70 receives an operation signal from a remote control 71 that remotely operates the television 34, and the CPU 52 processes the received operation signal so that a wireless remote control of a code necessary for the subordinate television 34 is obtained. A signal is appropriately output from the remote control output unit. Reference numeral 75 denotes a card ejection button for forcibly ejecting the card 80.
[0019]
FIG. 3 is a flowchart showing the operation procedure of the frequency subtraction program stored in the RAM 64. First, when the card 80 is inserted from a card insertion slot (not shown), the card transport unit 74 operates in step S20 to take the card 80 into the inside. At the same time, a read command is issued from the CPU 52, and the read / write circuit 72 operates to read the data in the card 80. The CPU 52 stores this data in the RAM 64.
[0020]
The card 80 stores data as shown in FIG. The card type code stores a code indicating that the card is a prepaid card. The system type card is a code stored in order to distinguish the card for another system from the card for the system. In addition, the card 80 stores the issuance frequency and issuance amount of the card 80, a rewritable current frequency and usage frequency, and a unique serial code for each card 80.
[0021]
Next, in step S21, the CPU 52 determines whether or not the system type code read into the RAM 64 matches the system type code. If the system type codes do not match, the CPU 52 interrupts the frequency subtraction process. Thereafter, the card transport unit 74 is controlled to eject the card 80 (step S28).
[0022]
On the other hand, if the system type codes match in step S21, the process proceeds to step S22 to determine whether or not the remaining number stored in the card is zero. If the remaining number is 0, the subsequent processing is interrupted, the card transport unit 74 is controlled, and the card 80 is ejected (step S28). That is, use of the card is not permitted. If the remaining number is not 0 but positive, the process proceeds to step S23 where the CPU 52 receives an operation signal from the remote controller 71 and sends a remote control signal corresponding to the operation signal from the remote control output unit 42 to the television 34. As a result, various operations of the television 34 including power on / off and channel change can be performed.
[0023]
Next, the CPU 52 takes in the output of the detection signal output circuit 43 constituting the load current detection circuit 38 from the port I1, and determines whether the subordinate television 34 is in use (step S24).
[0024]
Here, the operation of the load current detection circuit 38 will be described. One of the paths through which the AC input voltage is supplied from the AC power source to the television 34 is the diodes D1 to D4 and the diodes D5 to D5 that are inserted and connected to the power line 37A from the input terminal 35A. D8 passes through the output terminal 36A to the television 34, and the other passes from the input terminal 35B through the power line 37B to the television 34 through the output terminal 36B. When the power switch (not shown) of the television 34 is turned on and energized through the above path, the input side smoothing capacitor (not shown) built in the television 34 is charged during the positive half cycle of the AC input voltage. , The pulsed load current flows into the television 34 through the diodes D1 to D4 and the detection resistor R1, and the potential between both ends of the diodes D1 to D4 forming the series circuit, that is, both ends of the detection resistor R1, When the total Zener voltage of the diodes D5 to D8 is exceeded, a load current also flows through the diodes D5 to D8, and the voltage across the detection resistor R1 is limited there. Thereafter, when the charging of the smoothing capacitor on the television 34 side approaches, the load current flowing into the television 34 decreases, and the voltage across the detection resistor R1 drops from the limit level to zero.
[0025]
Further, when the power switch of the television 34 is turned off, a transition is made to a standby state. In the standby state, a load current (standby current) that is smaller than that in the energized state flows into the television 34. Therefore, although the load current is generated in a pulse shape as in the energized state, the time width is shortened by the amount of power consumption of the television 34 being small.
[0026]
In this series of operations, the total forward drop voltage FV of the diodes D1 to D4 is detected between both ends of the detection resistor R1 connected in parallel with the series circuit of the diodes D1 to D4 when the diodes D5 to D8 are turned on. A potential distributed by R1 is generated. If the detection resistor R1 does not exist, the voltage across the diodes D1 to D4 forming the series circuit is the forward drop voltage FV of the diodes D1 to D4 (for example, the individual diodes D1 to D4 at normal temperature). If the forward drop voltage is 0.7V, the combined forward drop voltage FV is 0.7V × 4 = 2.8V) itself. However, when the detection resistor R1 is present, the voltage across the diodes D1 to D4 is larger than that of the diodes D1 to D4 forming a series circuit alone due to the combined resistance value of the detection resistor R1 and the diodes D1 to D4 connected in parallel. It changes slowly, and the change of the waveform corresponding to the magnitude of the load current appears greatly. When the voltage between both ends of the diodes D1 to D4, that is, the voltage between both ends of the detection resistor R1 is applied to the light emitting diode 44A of the photocoupler CP1 through the resistor R2, the AC input voltage (50/60 Hz) whose pulse width varies greatly according to the load state. The detection signal output circuit 43 outputs an L level detection signal synchronized with ().
[0027]
On the other hand, in the negative half cycle of the AC input voltage, when the smoothing capacitor built in the television 34 starts to charge, a pulsed load current flows into the television 34 through the diodes D5 to D8 and the detection resistor R1, and eventually. When the potential between both ends of the detection resistor R1 exceeds the total Zener voltage of the diodes D1 to D4, load current also flows through the diodes D1 to D4, and the voltage across the detection resistor R1 is limited there. Is done. Thereafter, when the charging of the smoothing capacitor on the television 34 side approaches, the load current flowing into the television 34 decreases, and the voltage across the detection resistor R1 drops from the limit level to zero.
[0028]
In this case as well, when the voltage across the detection resistor R1 is applied to the light emitting diode 45B of the photocoupler CP2 through the resistor R2, the L is synchronized with an AC input voltage (50/60 Hz) whose pulse width changes according to the load state. A level detection signal is output from the detection signal output circuit 43.
[0029]
5 to 8 are voltage waveforms of respective parts in the standby state or the energized state, FIG. 5 is a voltage at the other end (measurement point P1 in FIG. 2) of the resistor R2 in the standby state, and FIG. 6 is a detection signal in the standby state. 7 shows the voltage at the line (measurement point P2 in FIG. 2), FIG. 7 shows the voltage at the measurement point P1 in the energized state, and FIG. 8 shows the voltage at the measurement point P2 in the energized state. In addition, in common with FIGS. 5-8, a vertical axis | shaft has shown voltage (1V / div) and the horizontal axis has shown time (5ms / div).
[0030]
As is clear from these drawings, the pulse width of the L level detection signal in the energized state is wider than the pulse width of the L level detection signal in the standby state. That is, returning to step S24 in FIG. 3, if the pulse width of the detection signal is less than a predetermined value, the CPU 52 constituting the device operation detecting means 26 is not in use (not used, stopped, or ended). If the pulse width of the detection signal is equal to or greater than a predetermined value, it is determined that the television 34 is in use. As described above, since the operation state can be determined only by comparing the pulse width of the detection signal with the predetermined value, the CPU 52 does not need to store the detection signal fetched from the detection signal output circuit 43 one by one. In this case, the CPU 52 takes in the L level detection signal from the input port I1 and manages the pulse width time of the detection signal that changes depending on the magnitude of the load current. Therefore, it is possible to accurately know whether or not the television 34 is in use.
[0031]
Thereafter, if the television 34 is in use, the process proceeds to step S25, where the current device usage status is displayed on a display unit (not shown), and the frequency of the television 34 determined by the usage fee per unit time. Based on the subtraction coefficient and the usage time counted by the timer 66, a subtraction process is performed in which a predetermined frequency is subtracted from the remaining frequency stored in the RAM 64 and updated as a new remaining frequency. That is, in this embodiment, the prepayment method is adopted.
[0032]
Next, in step S26, it is determined whether the remaining frequency is negative or positive. If the remaining number is positive, the CPU 52 writes the remaining number on the card by the read / write circuit 72. Then, as long as the television 34 is operating, the subtraction process is continued according to the timing of the timer 66. On the other hand, if the calculated remaining number is negative, the read / write circuit 72 writes the remaining number 0 to the card and forcibly sends a remote control signal for turning off the TV 34 from the remote control output unit 42. Then, the operation of the television 34 is stopped (step S27). Thereafter, the process is terminated, and the card 80 is discharged (step S28).
[0033]
By the way, when the remaining number is left in the card 80, in order to stop using the card 80, the card eject button 75 is pushed. When the button 75 is pressed, a signal is given to the interrupt port Io of the CPU 52, and the CPU 52 performs an interrupt operation. In the interrupt operation, the CPU 52 first stops the subtraction process. Further, the remaining number at that time is written in the card 80. Thereafter, the processing is terminated and the card 80 is discharged.
[0034]
Further, when taking out the card 80 is troublesome, the card 80 may be inserted and a power-off operation signal may be sent to the remote control light receiving unit 71 through the remote controller 70. In this way, a remote control signal for turning off the power is sent from the remote control output unit 42 to the television 34, and the power of the television 34 is turned off. When this happens, the detector 54 and thus the detection output of the detection circuit 60 also become zero, and the CPU 52 recognizes the off state of the television 34 and stops the subtraction process. In particular, the operation signal relating to the power on / off of the TV 34 sent from the remote controller 71 and the remote control signal from the remote control output unit 42 are the same alternate signals that are not distinguished by on / off, so the CPU 52 sends the remote control signal currently sent out. Cannot be directly recognized as a power-on signal or a power-off signal. In this regard, in the present embodiment, since the device operation detection means 26 can be used to accurately grasp the actual on / off state of the television 34, the television 34 is remotely controlled using the remote controller 70 which is a remote operation unit. Even in this case, it is possible to update the remaining frequency accurately.
[0035]
When the power switch of the television 34 is directly turned on without inserting the card 80, the detector 54 detects the leakage magnetic flux from the deflection yoke 38 and immediately sends it from the detection circuit 60 to the CPU 52. The CPU 52 determines that the television 34 is operating even though the card 80 is not inserted, and outputs a remote control signal for turning off the power from the remote control output unit 42. This prevents the TV 34 from being used without permission. When an operation signal corresponding to the channel of the free TV is sent from the remote control 70 to the remote control light receiving unit 71, the remote control output unit 42 outputs the TV 34 regardless of the presence of the card 80 or the remaining frequency of the inserted card 80. A remote control signal for turning on the power and a remote control signal corresponding to the channel are transmitted to the television 34. At that time, the subtraction processing of the card 80 is not performed. In this way, the free TV can be freely viewed from the TV 34 by the operation from the remote controller 70.
[0036]
As described above, the card system management apparatus 1 according to the present embodiment determines whether or not the television 34 that is a load to which the AC load voltage is applied is detected by the device operation detection unit 26, and if the television 34 is operating, In the one that updates the remaining frequency read from the rewritable card 80 according to the output of the time measuring means 32, the device operation detecting means 26 is a detection signal whose pulse width changes according to the magnitude of the load current flowing into the television 34. Is provided, and a load current detection circuit 38 serving as a load current detection means for outputting is provided, and the presence or absence of operation of the television 34 is determined according to the pulse width of the detection signal.
[0037]
In this case, when the television 34 operates and is in an energized state, a large amount of load current flows into the television 34. Therefore, a detection signal having a pulse width corresponding to this load current is output from the load current detection circuit 38. On the other hand, when the television 34 is not operating, for example, when the television 34 is in a standby state, the load current flowing into the television 34 is reduced only by the standby current, so the pulse width of the detection signal output from the load current detection circuit 38 is in the energized state. Narrower than. Therefore, for example, even for a load with a relatively large standby current, such as a television with video, if it is determined whether the pulse width of the detection signal has reached a predetermined value or more, the load current and the load voltage are both sampled. Thus, it is possible to accurately determine whether or not the load is in use without determining the value.
[0038]
When the load is off, almost no load current flows, and neither of the photocouplers CP1 and CP2 is turned on, and the L level detection signal may not be output. However, in this case, since the pulse width of the detection signal is zero, whether or not the load is in use is similarly determined by determining whether or not the pulse width of the detection signal has reached a predetermined value or more. Can be accurately determined, and there is no practical problem.
[0039]
In particular, in this embodiment, the first diodes D1 to D4 and the second diodes D5 to D8, which are one-way conductive elements, are inserted and connected to one AC power supply line 37A extending from the AC power supply to the television 34. A limiter circuit 42 connected in parallel to each other, a detection resistor 41 connected between both ends of the limiter circuit 42, and a detection signal output circuit 43 that extracts a voltage generated between both ends of the detection resistor 41 as a detection signal. A current detection circuit 38 is configured.
[0040]
In this way, the load current alternately flows through either one of the diodes D1 to D4 or the diodes D5 to D8. When the Zener voltage of another diode D5 to D8 or the diodes D1 to D4 is exceeded, both ends of the detection resistor 41 are detected. The voltage generated between them is limited. Therefore, even if the peak value of the load current is large, the voltage across the detection resistor 41 is limited to a constant value, and adverse effects on the detection signal output circuit 43 can be eliminated. In addition, by simply connecting the detection resistor R1 in parallel to the parallel circuit composed of the diodes D1 to D4 and the diodes D5 to D8, a voltage whose pulse width changes according to the magnitude of the load current is generated between both ends of the detection signal R1. Therefore, the presence or absence of the operation of the television 34 can be accurately determined with a simple circuit configuration.
[0041]
Further, the detection signal output circuit 43 connects a pair of photocouplers CP1 and CP2 in which light emitting diodes 44A and 44B as light emitting elements are connected in opposite directions, either directly or via a resistor R2 between both ends of the detection resistor R1. Composed. In this way, positive and negative voltages generated between both ends of the detection resistor R1 according to the load current can be output as detection signals by the pair of photocouplers CP1 and CP2, and in both positive and negative cycles of the AC input voltage, The presence or absence of the operation of the television 34 can be determined more accurately.
[0042]
The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention. In the above embodiment, one device is connected to the card system management apparatus 1, but two or more devices including at least one television 34 may be connected. Alternatively, only the remaining frequency of the RAM 64 may be updated until the card is discharged, and the remaining frequency of the card may be updated when the card is discharged. Further, in the above embodiment, the function of FIG. 1 is configured by the CPU 52 and its program, but part or all of the function may be configured by hardware logic.
[0043]
【The invention's effect】
According to the card system management apparatus of the present invention, the card system management device includes load current detection means for outputting a detection signal whose pulse width changes according to the magnitude of the load current flowing into the load, and the load is detected according to the pulse width of the detection signal. It is possible to accurately determine whether or not the load is in use without sampling the load current or load voltage and determining the value by having a device operation detection means that determines the presence or absence of the operation. Is possible.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a functional configuration of an entire card system management apparatus according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a hardware configuration of the card system management apparatus.
FIG. 3 is a flowchart showing a processing procedure of a program of the same power subtraction processing.
FIG. 4 is a schematic diagram showing the same prepaid card and the stored contents thereof.
FIG. 5 is a waveform diagram obtained by measuring the voltage at the other end of the resistor R2 in the standby state.
FIG. 6 is a waveform diagram obtained by measuring the voltage of the detection signal line in the standby state.
FIG. 7 is a waveform diagram obtained by measuring the voltage at the other end of the resistor R2 in the energized state.
FIG. 8 is a waveform diagram obtained by measuring the voltage of the detection signal line in the energized state.
FIG. 9 is a block diagram showing a conventional card system management apparatus.
FIG. 10 is a graph showing changes in load current.
[Explanation of symbols]
26 Device operation detection means
32 Timekeeping
34 TV (load)
38 Load current detection circuit (load current detection means)

Claims (1)

Card system management that determines whether or not a load to which an AC load voltage is applied is operated by the device operation detection means, and updates the remaining frequency read from a rewritable card according to the output of the timing means if the load is operating In the apparatus, the device operation detection means includes load current detection means for outputting a detection signal whose pulse width changes according to the magnitude of the load current flowing into the load, and the load is detected according to the pulse width of the detection signal. A card system management device for determining whether or not the operation of the card system is performed.

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