The present invention relates to a system in which a moving machine such as an automobile, a robot, or the like is remote-controlled and in particular, to a remote control system in which a plurality of moving machines are controlled at the same place and at the same time and which is suitable for a case in which there is a need to cause interaction based on communication between the moving machines, and to a moving machine thereof.
When a plurality of moving machines are remote-controlled at the same place by utilizing infrared radiation or radio waves and communication is carried out between the moving machines by utilizing infrared radiation or radio waves, signals transmitted from the transmitter to the moving machine and signals between the moving machines interfere with each other, and therefore, there is the fear that accurate control and communication will be difficult. As a technique solving such a problem, for example, the system disclosed in Japanese Patent No. 2713603 is well-known. In this system, a transmitter has a transmitting device which transmits, by radio waves, data for remote-controlling a corresponding moving machine. Further, the moving machine has a transmitting device which transmits, by infrared radiation, data for communicating with another moving machine, a device which receives data by radio waves, and a device which receives data by infrared radiation. In accordance therewith, a remote control operation system is realized in which signals transmitted from the transmitter and signals from the moving machine are prepared from interfering with each other, and a plurality of moving machines are remote-controlled at a same place, and communication between the moving machines is carried out.
In the above-described remote control system, a moving machine needs two different receiving devices, which are a device which receives radio waves transmitted from a transmitter and a device which receives infrared radiation transmitted from another moving machine, and a processing system. Therefore, the drawbacks that the structure of the moving machine is complicated and the electric power consumption increases arise.
Here, the object of the present invention is to provide a remote control system in which a plurality of moving machines are remote-controlled without leading to complexity of the structure of the moving machine and an increase in electric power consumption, and which can cause interaction based on communication between the moving machines.
In order to solve the above problems, according to the present invention, there is provided a remote control system in which operations of a plurality of moving machines which are readied for a plurality of transmitters, respectively, are individually controlled by the plurality of transmitters and interaction is caused between the plurality of moving machines based on communication,
each of the plurality of transmitters comprising: an operation data preparing device which prepares operation data including identification information which is for identifying each of the plurality of transmitters and is unique to each of the plurality of transmitters, operation control information for controlling an operation of one of the plurality of moving machines, and communication control information for controlling the communication between the moving machines; an operation data transmitting device which transmits the operation data; an operation data receiving device which receives the operation data transmitted from another one of the plurality of transmitters; a transmission timing setting device which sets a transmission timing of self operation data on the basis of the identification information contained in the received operation data; and an operation data transmission controlling device which makes the data transmitting device transmit the operation data according to the set transmission timing,
each of the plurality of moving machines comprising: a communication data preparing device which prepares communication data for making another one of the plurality of moving machines execute a predetermined processing; a communication data transmitting device which transmits the communication data; a data receiving device which receives the operation data transmitted from each of the plurality of transmitters and the communication data transmitted from said another one of the plurality of moving machines; and a moving machine controlling device which, when the operation data containing the identification information unique to one of the plurality of transmitters corresponding to oneself is received, controls self operation on the basis of the operation control information contained in the received operation data, and controls preparation and transmission of the communication data on the basis of the communication control information contained in the received operation data, and which, when the communication data from said another one of the plurality of moving machines is received, executes the predetermined processing corresponding to the received communication data,
wherein for the plurality of transmitters and moving machines, a common data transmission schedule, which is stipulated such that the transmission timing of each of the operation data and the communication data does not overlap each other, is set, the transmission timing setting device of each of the plurality of transmitters refers to the identification information contained in the operation data from said another one of the plurality of transmitters, and specifies the transmission timing of self operation data stipulated by the data transmission schedule, and the moving machine controlling device refers to a receiving timing of the operation data transmitted from at least one of the plurality of transmitters, and specifies a transmission timing of self communication data stipulated by the data transmission schedule, and makes the communication data transmitting device transmit the communication data according to the specified transmission timing.
According to the remote control system of the present invention, each transmitter, by receiving data transmitted from another transmitter, and each moving machine, by referring to the receipt timing of data transmitted from each transmitter, can transmit self data according to a data transmission schedule provided such that transmission timings of each transmitter and each moving machine do not overlap. Accordingly, the data from each transmitter and the data from each moving machine can be transmitted on the same carrier signal, and sharing, at each moving machine, of a receiving device and a processing system of the signals from the transmitter and the signals from the moving machine, can be advanced. In accordance therewith, without leading to complexity of the structure of the moving machine and an increase in electric power consumption, a plurality of moving machines can be remote-controlled and interaction based on communication can be caused between the moving machines.
Further, the remote control system of the present invention can include the following modes.
The data transmission schedule may be stipulated such that the transmission timing of each of the operation data and the communication data cyclically arrives in a predetermined order.
In this way, by only stipulating the transmission schedule of one period of operation data and communication data, each transmitter and each moving machine can specify a period in which the self data can be transmitted. Further, because data transmission is carried out each period, even if one part of the transmitters cuts off data transmission in the midst thereof, another transmitter and moving machine can specify the period allocated to themselves and transmit data.
In each cycle, periods in which the plurality of transmitters are allowed to transmit the operation data, respectively, may be stipulated so as to have time lengths equal to each other, and periods in which the plurality of moving machines are allowed to transmit the communication data, respectively, may be stipulated so as to have time lengths equal to each other.
In this way, by only stipulating the order of data transmission of each transmitter and each moving machine in a predetermined period, each transmitter and each moving machine can specify a period in which the self data can be transmitted. For example, when a time length of the transmission period of the transmitter is T1 and a time length of the transmission period of the moving machine is T2, a transmitter and a moving machine, whose transmission timing is set after the ith transmitter and the jth moving machine as counted from the transmitter whose transmission timing is set to be first, may start transmission after T1×i+T2×j from the first transmission start time.
The data transmission schedule may be stipulated such that the transmission timing of the communication data of one of the plurality of moving machines arrives next after the transmission timing of the operation data of one of the plurality of transmitters which corresponds to said one of the plurality of moving machines.
In this way, merely by starting transmission of the self transmission data immediately after receiving operation data from the transmitter corresponding to oneself, the moving machine can carry out the transmission without overlapping on the transmission timings of the transmitter and the other moving machines.
When said one of the plurality of moving machines receives the communication data transmitted from another one of the plurality of moving machines, said one of the plurality of moving machines may specify said another one of the plurality of moving machines on the basis of the identification information contained in the operation data received immediately before receipt of the communication data transmitted from said another one of the plurality of transmitters.
In this case, even if identification information is not added to the transmission data, it can be judged from which of the moving machines the transmission data is transmitted. Therefore, information which can be added to one block of communication data can be reduced, or the transmission/receiving time data can be shortened by reducing one block of communication. Also, when the transmission timing of the moving machine next corresponding to the transmitter is set, only the identification information contained in the operation data received immediately before is held, and it may merely be referred to, and the burden on the hardware can be reduced.
When each of the plurality of moving machines receives the operation data transmitted from each of the plurality of transmitters or the communication data transmitted from each of the plurality of moving machines, each of the plurality of moving machines judges whether the received data is either of the operation data or the communication data by comparing a receiving timing of the received data and the transmission timing of each of the plurality of transmitters and each of the plurality of moving machines stipulated by the data transmission schedule.
In this case, there is no need to add to the data information for judging whether it is either of operation data or communication data, and information which can be added to one block of data can be reduced, or the transmission/receiving time can be shortened by reducing one block of data.
According to the present invention, there is provided a moving machine which is combined with a transmitter capable of transmitting operation data including identification information for identifying oneself, operation control information for controlling an operation of one of objects of control, and communication control information for controlling communication between said objects of control, and which is used as said one of the objects of control, the moving machine comprising: a communication data preparing device which prepares communication data making another moving machine execute a predetermined processing; a communication data transmitting device which transmits the communication data; a data receiving device which receives the operation data transmitted from the transmitter and the communication data transmitted from said another moving machine; and a moving machine controlling device which, when the operation data containing the identification information unique to the transmitter corresponding to oneself is received, controls self operation on the basis of the operation control information contained in the operation data, and controls preparation and transmission of the communication data on the basis of the communication control information contained in the operation data, and which, when the communication data from said another moving machine is received, executes a predetermined processing corresponding to the received communication data, wherein the moving machine controlling device refers to a receiving timing of the operation data transmitted from the transmitter to be combined with oneself or another transmitter, and specifies a self transmission timing which is stipulated, by a predetermined data transmission schedule shared by the transmitter to be combined with oneself, said another transmitter and said another moving machine, such that the transmission timing of the operation data from each of the transmitter to be combined with oneself and said another transmitter and the transmission timing of the communication data from said another moving machine do not overlap each other, and makes the communication data transmitting device transmit the communication data according to the specified transmission timing.
The remote control system of the present invention can be structured if, at each transmitter, devices are provided which ready a transmitter for each moving machine, set the same identification information for a moving machine and a transmitter which form a set, set a common data transmission schedule stipulated such that the transmission timings do not overlap, specify the self transmission timing stipulated by the data transmission schedule by receiving data from another transmitter, and control the transmission timing.
Note that the moving machine of the present invention may include various types of preferable modes in the above-described remote control system. Namely, the aforementioned data transmission schedule may be stipulated such that transmission timing of each of the operation data and the communication data cyclically arrives in a predetermined order. In each cycle, a period in which the moving machine is allowed to transmit the communication data may be stipulated so as to be a time length equal to a period in which said another moving machine is allowed to transmit the communication data. The aforementioned data transmission schedule may be stipulated such that the transmission timing of communication data arrives next after the transmission timing of operation data of the transmitter to be combined with oneself. When the communication data transmitted from said another moving machine is received, the moving machine specifies said another moving machine which transmitted the communication data on the basis of the identification information contained in the operation data received immediately before receipt of the communication data. When the operation data which is transmitted from each of the transmitter to be combined with oneself and said another transmitter or the communication data transmitted from said another moving machine are received, it is judged whether the received data is either the operation data or the communication data by comparing the receiving timing and the transmission timing stipulated by the data transmission schedule.
Transmitters 2 . . . 2 are readied in a one-to-one correspondence with the respective moving machines 1 . . . 1. The numbers 1, 2 are set as IDs for the moving machines 1 . . . 1 and the transmitters 2 . . . 2, respectively. Each moving machine 1 is remote-controlled on the basis of data from the transmitter 2 to which the same ID is given. Infrared radiation is utilized for remote-control of each moving machine 1. Therefore, a remote control signal light-emitting section 3 is mounted to each transmitter 2, and a remote control signal light-receiving section 4 is mounted to each moving machine 1. Moreover, in order to synchronize data the transmission from each transmitter 2, a remote control signal light-receiving section 5 is mounted to each transmitter 2. Further, infrared radiation is utilized for communication between the moving machines 1 . . . 1 as well. Therefore, a remote control signal light-emitting section 6 is mounted to each moving machine 1 in order to carry out communication with the other moving machine and the aforementioned remote control signal light-receiving section 4 of the moving machine 1 also receives signals from the remote control signal light-emitting section 6 of the other moving machine 1.
Hereinafter, as an embodiment of the remote control system of the present invention, a toy remote-controlling a miniature tank model 30 shown in
The barrel 42 is provided at the turret section 32. A light-emitting section 43 (corresponding to the remote control signal light-emitting section 6 of
Alight-receiving section 46 (corresponding to the remote control signal light-receiving section 4 of
A control device 48, in which a microprocessor, an oscillator, a memory, a motor driver, and the like are disposed on the same substrate, is provided at the interior of the tank model 30. The control device 48 judges whether the data sent from the light-receiving section 46 is from the transmitter 10 corresponding to the self tank model 30 or is from another tank model 30. When it is judged to be data from the transmitter 10 corresponding to the self tank model 30, on the basis of the data, the control device 48 controls operations of the motors for travelling 38 . . . 38 and the turret motor 41, and transmits the data from the light-emitting section 43 to another moving machine. When it is judged to be data from another tank model 30, the control device 48 executes a predetermined processing for the time of being hit.
On the other hand, the remote control signal light-receiving section 13 shown in
Note that, a dry cell as a power source, a power source circuit converting the electric current/voltage of the dry cell to a predetermined electric current/voltage, an oscillator providing a clock signal to the microcomputer 60, a charging circuit or a charging terminal charging a secondary cell as the power source of the tank model 30, and the like are provided (not shown) at the transmitter 10 in addition to the power source switch 18 shown in
When the signal from the transmitter 10 corresponding to the self tank model 30 is received, on the basis of the received data, the microcomputer 70 provides an instruction to drive the motors for travelling 38 . . . 38 to a motor driver 72, and an instruction to drive the turret motor 41 to a motor driver 73. Moreover, if there is an instruction to fire in the received data, the microcomputer 70 generates data to be transmitted to the other tank model 30, and provides an instruction to transmit the data to the remote control signal light-emitting section 43 at a transmission timing based on the time when the data is received from the transmitter 10. Here, transmitting the data at a transmission timing based on the time when the data is received from the transmitter 10 is for preventing radio interference due to simultaneous transmission of remote control data from a plurality of the transmitters 10 and a plurality of the tank models 30. The remote control signal light-emitting section 43 is structured so as to include a light-emitting device such as, for example, an LED or the like.
When a signal from the other tank model 30 is received, on the basis of the received data, the microcomputer 70 makes remote control operation impossible for a constant time, or executes a processing for the time of being hit, such as lighting an LED or the like.
A secondary cell as a power source, a power switch switching the ON/OFF of the power source, a power source circuit converting the electric current/voltage of the secondary cell to a predetermined electric current/voltage, an oscillator providing a clock signal to the microcomputer 70, a nonvolatile memory for holding the ID allocated to the self tank model 30, and the like are provided (not shown) at the tank model 30 in addition to an LED 74 showing that the tank model 30 is in an operating state.
The one block of remote control data generated by the microcomputer 60 of the transmitter 10 is structured from an ID code, control information of the left and right motors for travelling, control information for the turret, and firing instruction information. Data corresponding to an ID selected by the ID switch 17, for example, data of 2 bits, is set at the ID code portion. At each of the control information portions of the left and right motors for travelling, data of 1 bit designating the driving direction and data of 3 bits designating the speed are set in correspondence with operated positions of the travelling control levers 14. At the control information for the turret motor, data of 1 bit instructing whether to turn or not and data of 1 bit for designating a direction of rotation are set in correspondence with the operation of the turret section control dial 15. At the firing instruction information, data of 1 bit designating whether to fire or not is set in correspondence with operation of the firing key 16. Note that the number of bits of one block of remote control data is always constant. Accordingly, the time needed for transmitting one block of remote control data is constant.
One block of remote control data generated in the microcomputer 70 of the tank model 30 is structured from additional information making the other tank model 30 execute a predetermined processing. In the present embodiment, the additional information is not necessarily needed. However, various changes can be applied by the additional information to the predetermined processing which the hit tank model 30 executes. Note that the number of bits of one block of remote control data is always constant. Accordingly, the time needed for transmitting one block of remote control data is constant.
When four sets of the transmitters 10 for which ID=1-4 are set and the tank models 30 which are objects of control thereof are used at the same time, the transmission timing of each set is set at a period different from those of the other sets, and further, the transmission timings of the respective transmitters 10 and tank models 30 are set to periods different from each other. The length of time in which one set of the transmitter 10 and the tank model 30 transmits remote control signals is T3, and each transmitter 10 and each tank model 30 repeats transmission of remote control signals at a period T4 (=4×T3) corresponding to the number of sets×transmission time length T3. Further, the transmission timing of each set is shifted in order by T3 from ID=4. Moreover, the transmission time length T3 of each set is structured from a transmission time length T1 of the transmitter 10 and a time length T2 which follows T1 and in which transmission of the tank model 30 is allowed. Due to each transmitter 10 and each tank model 30 managing the transmission timing according to such a relationship, it is possible for the transmission periods from the four transmitters 10 and the four tank models 30 to not overlap on each other.
In order to realize such transmission control, for example, if there are the transmitter 10 and the tank model 30 of ID=3 of
Note that, here, a case in which there are four sets of the transmitters 10 and the tank models 30 was described. However, by adding IDs, the transmission timing can be controlled in the same way even in a case in which there are five or more sets. The period of the transmission timing of each transmitter 10 and each tank model 30 is N×T3 (N is the number of sets). However, a blank period in which data is not transmitted is respectively set between periods in which each transmitter 10 and each tank model 30 are transmitting data, and in accordance therewith, the entire period may be set to be longer than N×T3.
Next, it is judged whether the timer set at step S1 is time-over or not (step S5). If the timer is not time-over, the routine returns to step S2. When the time is over, transmission of data remote-controlling the self tank model 30 is started (step S6). However, the actual time of starting output is the time at which the transmission timing set at step S4 has been reached. If no data has been received up until time over, there is single operation, i.e., there is no other transmitter 10. Therefore, transmission of data is immediately started at step S6.
When the processing of step S6 is completed, the microcomputer 60 controls data transmission according to the procedures of normal operation of
When it is judged that time is up at step S14, transmission of the self data is started (step S15). At this time, receipt of data is carried out in parallel. Next, it is judged whether the data transmission is completed or not (step S16), and if the transmission is completed, the transmitted data and the data received in parallel with the transmission are compared (step S17). If the transmitted data and the received data do not coincide, it is judged that radio interference has arisen, and the routine proceeds to the power-on operation of
The transmission timing of the self tank model 30 can be adjusted by the timer, and whether the received data is data from the transmitter 10 or from another tank model 30 can be specified from the time when the data was received. The setting of the timer and the referring to the data transmission schedule may be carried out, for example, as follows. First, when remote control data having the same ID as the ID allocated to the self tank model 30 (i.e., transmission data from the transmitter 10 corresponding to the self) is received, at the time of completion of receiving, the time T2 is set at the timer and a flag expressing that it is the transmission time of the tank model 30 is set. Thereafter, operation in which, at the point in time when the timer-count has passed by time T2, T1 is reset and the flag is reset, and at the point in time when the timer-count has passed by time T1, time T2 is reset and the flag is set, is repeated. In accordance therewith, whether the time of receiving the data is the transmission time of the transmitter 10 or the transmission time of the tank model 30 can be distinguished. Moreover, if a counter variable is prepared, the counter variable is initialized in the transmission time of the self tank model 30. Thereafter, by increasing the counter variable each time the flag, which expresses that it is the transmission time of the tank model 30, is set, even when the transmission data from the transmitter 10 corresponding to oneself is cut-off, the self transmission timing can be known, and the ID of the received remote control data can be specified.
After the timer is set at step S22, it is judged whether there is a firing instruction or not in the firing instruction information contained in the received data (step S23). When there is a firing instruction, data transmitted to another tank model 30 is generated, and the data is transmitted at a predetermined timing (step S24). Thereafter, on the basis of the left and right motor for travelling control information and the turret motor control information contained the received data, motor-control is carried out (step S25), and the routine waits for the next receipt.
At step S21, if the ID contained in the received data does not match the ID allocated to the self tank model 30, the receiving time and the data transmission schedule set at step S22 are compared, and it is judged whether the receiving time is the transmitting time of another tank model 30 or not (step S26). When it is judged that the receiving time is not the transmission time of the tank model 30 (namely, that it is the transmission data from the transmitter 10 corresponding to another tank model 30), T2 is reset at the timer for referring to the data transmission schedule, and thereafter, due to the counting and setting of T2 and T1 being repeated, the data transmission schedule is corrected (step S27). Next, the ID contained in the received data is set to a variable for storing the ID of the received data (step S28).
At step S26, when it is judged to be the transmission time of another tank model 30, the ID substituted in at step S28 is referred to. In the present embodiment, as shown in
The present invention is not limited to the above-described embodiment, and may be implemented in various forms. For example, the moving machine is not limited to a tank, and may be a machine imitating various moving bodies. Interaction based on communication between the moving machines is not limited to firing, and may be conversation or the like. The light-receiving section of the moving machines is not limited to one, and a plurality of light-receiving sections may be provided. One part of the plurality of light-receiving sections may be used for receiving transmission data from a transmitter, and the other light-receiving sections may be used for receiving transmission data from another moving machine. The transmitter may be hand-holdable by an operator, or may be a type which is placed on a floor. A specific program may be installed into a portable machine such as a portable game machine or a portable telephone, and it may be made to function as a transmitter.
As described above, according to a remote control system of the present invention, each transmitter, by receiving data transmitted from another transmitter, or each moving machine, by referring to receiving timing of data transmitted from each transmitter, can transmit self data according to a data transmission schedule stipulated such that transmission timings of each transmitter and each moving machine do not overlap. Accordingly, the data from each transmitter and the data from each moving machine can be transmitted on the same carrier signal, and, at each moving machine, the sharing of a receiving device and a processing system of signals from the transmitter and signals from over moving machines can be advanced. In accordance therewith, without leading to complexity of a structure of the moving machine and an increase of electric power consumption, a plurality of moving machines can be remote-controlled and interaction based on communication can be brought about among the moving machines.
Number | Date | Country | Kind |
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2001-303567 | Sep 2001 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP02/10076 | 9/27/2002 | WO | 00 | 4/28/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/028837 | 4/10/2003 | WO | A |
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Number | Date | Country | |
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20040249506 A1 | Dec 2004 | US |