CN111192503A

CN111192503A - Block type wireless coding command input device and method

Info

Publication number: CN111192503A
Application number: CN201910296942.1A
Authority: CN
Inventors: 朴龙圭
Original assignee: Miluth Inc
Current assignee: Miluth Inc
Priority date: 2018-11-15
Filing date: 2019-04-11
Publication date: 2020-05-22
Also published as: KR20200057138A; KR102186719B1

Abstract

According to one embodiment of the present invention, a block-type radio encoding command input device and method includes: a master block; the coding block assembly comprises at least two coding blocks which are sequentially connected with the main block; and a device for receiving program codes corresponding to at least two encoding blocks connected to the main block from the main block and performing an operation based on the received program codes, at least one of the at least two encoding blocks may be a storage block for controlling an operation of the device based on the stored program codes.

Description

Block type wireless coding command input device and method

Technical Field

The application relates to a BLOCK TYPE wireless CODING COMMAND input device AND METHOD (BLOCK TYPE APPATUS FOR WIRELESSLY INPUTTING CODING COMMAND AND METHOD USENTHEOF).

Background

In general, in order to develop an application program used in a device such as a robot, it is necessary to receive training on a programming language such as C, and also to receive training on an algorithm having logic so that the application program can be encoded on some basis and rule by using the programming language.

Training for algorithms is the process of learning a logical language, which is the process of learning to select certain ones for connection. It is therefore important to understand the underlying concepts of these logical languages (e.g., how to understand how loop instructions operate, how to make decisions, how to perform calculations, how to obtain information provided to our computer, how to cause the computer to work, etc.) and to let the user experience the creative experience and achievements with respect to the objects that the user has created.

In particular, for children, compared to the program coding in text form using a computer or a smart device, the coding training in an un-plugged programming manner without using a computer, which can enable children to explore through five senses and naturally grasp the basic principle of programming through a tactile activity while enhancing a visual stimulation effect by using a multi-colored block (transparent block) that can be touched by hand, is more effective.

As a prior art for naturally improving the logical thinking of children through such algorithm training, korean registered patent No. 1843831 discloses an "Unplugged Real Coding Block". According to such prior art, by connecting a plurality of blocks of a structure similar to an actual program statement, interest can be stimulated and the link with an actual coding statement can be enhanced.

However, according to the above-described conventional technique, since a plurality of encoding blocks need to be continuously connected at the time of program encoding, a large number of encoding blocks are required at the time of performing repetitive operations, and a plurality of encoding blocks can be executed as a whole and a part of the encoding blocks cannot be executed, so that it is difficult to eliminate a failure and a modification error.

Documents of the prior art

Patent document

(patent document 1) korean registered patent No. 1843831 ("code block without power on", registration date: 2018, 03 month, 26)

Disclosure of Invention

According to an embodiment of the present invention, there is provided a block type wireless coded command input apparatus and method that can perform various programming using a small number of blocks and utilize a coding block capable of correcting errors and removing malfunctions.

According to one embodiment of the present invention, there is provided a block-type wireless coded command input device including: a master block; the coding block assembly comprises at least two coding blocks which are sequentially connected with the main block; and a device for receiving program codes corresponding to at least two of the encoding blocks connected to the main block from the main block, at least one of the at least two encoding blocks may be a storage block for controlling an operation of the device based on the stored program codes, and performing an operation based on the received program codes.

According to an embodiment of the present invention, the main block may transmit a phased execution command to the device each time an input of the phased execution command is received, and the device may sequentially execute a part of the program code corresponding to at least two of the encoding blocks one by one each time the phased execution command is received to remove a failure.

According to an embodiment of the present invention, the block-type wireless coded command input apparatus may further include a device block that is connectable only with the main block and identifies a device that is operable by the coded block assembly.

According to an embodiment of the present invention, the device block may include: a communication unit; a storage section for storing unique identification code information of a device operable by the encoding block assembly; and a control part capable of transmitting the stored unique identification code information of the device to the master block through the communication part when the control part is connected to the master block; the master block is capable of displaying an error when the unique identification code information of the device received from the device block is not identical to the unique identification code information of the device received from the device block.

According to an embodiment of the present invention, the memory block may include: a communication unit; a storage section for storing a unique identification code and program codes corresponding to at least two encoding blocks; a control unit capable of transmitting the unique identification code and the program codes corresponding to the at least two coding blocks stored in the storage unit to the master block through the communication unit when the control unit is connected to any one of the at least two coding blocks or the master block; and a display section for displaying an execution state of the memory block.

According to an embodiment of the present invention, the memory block may include: a communication unit; a storage section for storing a unique identification code; a control unit capable of transmitting the unique identification code to the master block through the communication unit when the control unit is connected to any one of the at least two code blocks or the master block; and a display section for displaying an execution state of the memory block.

According to an embodiment of the present invention, the encoding block may include: a function block having a unique identification code and for moving and rotating the device; a function block having a unique identification code and for repeating an operation of the apparatus; a function block having a unique identification code and used for termination; and the memory block for performing a function of at least one of the function blocks.

According to an embodiment of the present invention, the main block may include: a communication unit; a storage unit configured to store unique identification codes of at least two of the encoding blocks and program codes corresponding to the unique identification codes; a control section that generates a program code based on unique identification codes of at least two of the coding blocks sequentially connected to the main block by referring to the storage section, and transmits the generated program code to the device through the communication section; an input section for receiving an input of a total execution command or a staged execution command of program codes corresponding to at least two of the encoding blocks; and a display section for displaying an execution state of the program codes in different colors, the control section transmitting the total execution command or the staged execution command to the apparatus through the communication section, the apparatus being capable of executing all the program codes corresponding to at least two of the encoding blocks based on the total execution command, or the apparatus executing a part of the program codes corresponding to at least two of the encoding blocks one by one in stages each time the staged execution command is received.

According to an embodiment of the present invention, the function block may include: a communication unit; a storage unit for storing, for each function block, a unique identification code of the corresponding function block, a voltage of a variable block connected to the corresponding function block, and any one of a rotation angle, a movement distance, and a number of repetitions corresponding to the voltage of the variable block; a control part capable of reading a voltage from a variable block when connected to the variable block, and transmitting any one of a rotation angle, a movement distance, and a number of repetitions corresponding to the read voltage to the main block through a communication part by referring to the storage part; and a display section for displaying an execution state of the function block.

According to an embodiment of the present invention, the encoding block assembly further includes the variable block associated with any one of a rotation angle, a movement distance, and a number of repetitions of the device, the variable block including: a power source; the load resistor is connected with a power supply at one end; a plurality of resistors having different resistance values, respectively; and a rotary switch that is rotated in one direction so that the other end of the load resistor is connected to one of the plurality of resistors, wherein the variable block may be configured to be capable of outputting different voltages according to a rotation angle of the rotary switch.

According to an embodiment of the present invention, the end block may include: a communication unit; a storage section for storing a unique identification code; and a control unit that transmits the unique identification code to the master block through the communication unit when the control unit is connected to any one of the at least two code blocks.

According to one embodiment of the present invention, there is provided a block type wireless coding command input method, including: the method comprises the following steps that firstly, at least two coding blocks are sequentially connected with a main block to form a coding block assembly; a second step of transmitting, in the coding block assembly, program codes corresponding to at least two of the coding blocks sequentially connected to the main block to a device; and a third step of performing an operation based on the received program code in the apparatus; at least one of the at least two encoding blocks is a storage block for controlling the operation of the apparatus based on stored program code.

According to an embodiment of the present invention, it is possible to perform various kinds of programming with a small number of blocks by using a memory block and to execute a part of a plurality of coding blocks, thereby having advantages of correcting errors and removing malfunctions. In addition, there is an advantage that it is possible to operate in a specific device by adding a device block.

Drawings

Fig. 1 is an overall configuration diagram of a block type wireless coded command input device according to an embodiment of the present invention.

Fig. 2a is a block diagram of a main block and a diagram showing an external appearance according to an embodiment of the present invention.

Fig. 2b is a block diagram of functional blocks according to an embodiment of the present invention and a diagram showing an external appearance.

Fig. 2c is a block diagram of a device block and a diagram showing an external appearance according to an embodiment of the present invention.

Fig. 2d is a block diagram of a variable block according to an embodiment of the present invention and a diagram showing an external appearance.

Fig. 2e is a block diagram of a memory block according to an embodiment of the present invention and a diagram showing an appearance.

Fig. 3 is a flowchart illustrating a block type wireless coding command input method according to an embodiment of the present invention.

Description of the reference numerals

100: block-type wireless coded command input device 200: coding block assembly

210: the main block 220: function block

230: variable block 240: equipment block

250: the storage block 300: equipment (robot)

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various different forms, and the scope of the present invention is not limited to the embodiments described below. For the sake of clarity, the shapes, sizes, and the like of the constituent elements in the drawings may be exaggerated, and the constituent elements shown by the same reference numerals in the drawings are the same constituent elements.

Fig. 1 is an overall configuration diagram of a block type wireless coded command input device according to an embodiment of the present invention. In addition, fig. 2a is a block diagram of a main block and a diagram showing an external appearance according to an embodiment of the present invention, fig. 2b is a block diagram of a function block and a diagram showing an external appearance according to an embodiment of the present invention, fig. 2c is a block diagram of a device block and a diagram showing an external appearance according to an embodiment of the present invention, fig. 2d is a block diagram of a variable block and a diagram showing an external appearance according to an embodiment of the present invention, and fig. 2e is a block diagram of a memory block and a diagram showing an external appearance according to an embodiment of the present invention.

First, as shown in fig. 1, a block-type wireless coded command input apparatus 100 according to an embodiment of the present invention may include: a main block 210; a coded block assembly 200 comprising at least two coded

blocks

220, 250 connected in series with a main block 210; and an apparatus 300 for receiving program codes corresponding to the at least two

encoding blocks

220, 250 connected to the main block 210 from the main block 210 and performing an operation based on the received program codes; wherein at least one of the at least two

encoding blocks

220, 250 connected in sequence may comprise a storage block 250, the storage block 250 being configured to control the operation of the apparatus 300 based on the stored program code.

In addition, according to an embodiment of the present invention, the encoding block assembly 200 may further include a variable block 230 and a device block 240, the variable block 230 being associated with a rotation angle, a movement distance, and a number of repetitions of the device 300, the device block 240 being connectable only to the main block 210 and used to identify devices that can be operated by the encoding block assembly 200.

It should be noted that, although the device 300 is described on the premise that the device 300 is a robot in the description of the present invention, according to different embodiments, the device 300 may include various devices such as a smart phone, a pda (personal digital assistants), a pc (personal computer), a tablet computer (tablet computer), and a notebook computer (notebook computer) that can be executed by receiving program codes from the main block 210.

Specifically, as shown in fig. 1, the encoding block assembly 200 may include a main block 210 and at least two

encoding blocks

220 and 250 sequentially connected to the main block 210, wherein when the at least two encoding blocks are connected to the main block 210, the main block 210 may transmit program codes corresponding to the connected at least two

encoding blocks

220 and 250 to the device 300.

Fig. 2a is a block diagram of a main block 210 according to an embodiment of the present invention and a diagram showing an external appearance.

As shown in fig. 1 and (a) of fig. 2a, the main block 210 may include: a communication unit 211; a storage unit 212 for storing unique identification codes of at least two coding blocks and corresponding program codes; a control part 213 generating a program code based on unique identification codes of at least two coding blocks sequentially connected to the main block 210 by referring to the storage part 212 and transmitting the generated program code to the apparatus 300 through the communication part 211; an input section 214 for receiving an input of a total execution command or a staged execution command of the program codes corresponding to at least two encoding blocks; and a display section 215 for displaying the execution state of the program code in different colors.

Further, (b) of fig. 2a shows the appearance of the main block 210, and reference numeral 214a corresponds to a total execution button, reference numeral 214b corresponds to a staged execution button, reference numeral 214c corresponds to a power button, and reference numeral 214d corresponds to a display section.

According to the above configuration, the control section 213 can transmit the total execution command generated by pressing the total execution button 214a or the staged execution command generated by pressing the staged execution button 214b to the device 300 through the communication section 211. The apparatus 300 receiving the above-described total execution command may execute all the program codes corresponding to at least two encoding blocks according to the total execution command or execute a part of the program codes corresponding to at least two encoding blocks in stages one by one each time a staged execution command is received, and thus has an advantage that a malfunction can be eliminated.

Table 1 below illustrates an exemplary operation when the

buttons

214a, 214b of the main block 210 are pressed, and table 2 exemplarily illustrates a display state of the display portion 215a of the main block 210. In table 1, the long press means a case where the

buttons

214a and 214b are pressed for at least 2 seconds or more, and the sub block in table 2 may be any one of the function block 220, the storage block 250, and the device block 240 other than the main block 210. In addition, darsh (Dash) of table 2 may be an inherent name of the device 300 of fig. 1. The colors of table 2 are only helpful for understanding the present invention, and it is obvious to those skilled in the art that they may be changed to other colors.

[ TABLE 1 ]

[ TABLE 2 ]

In addition, the encoding blocks 220, 250 may include a function block 220 and a storage block 250 sequentially connected to the main block 210.

Fig. 2b is a block diagram of a function block 220 according to an embodiment of the present invention and a diagram showing an external appearance.

As shown in fig. 1 and fig. 2b (a), the function block 220 may include: a communication unit 220 a; a storage part 220b for storing, for each function block, a unique identification code of the corresponding function block, a voltage of the variable block 230 connected to the corresponding function block, and any one of a rotation angle, a movement distance, and a repetition number corresponding to the voltage; a control part 220c for reading a voltage from the variable block 230 when connected with the variable block 230, and transmitting any one of a rotation angle, a movement distance, and a number of repetitions corresponding to the read voltage to the main block 210 through the communication part 220a by referring to the storage part 220 b; and a display unit 220d for displaying the execution state of the function block 220.

The above-described configuration of fig. 2b (a) can be applied to the case of the function block 221 for movement (forward or backward) of the apparatus 300, the function block 222 for rotation of the apparatus 300, and the pair of function blocks 223 for repetitive operations of the apparatus 300.

When the function Block 220 is a function Block for ending (End Block), 224, it may include: a communication unit 220 a; a storage section 220b for storing the unique identification code; and a control block 220c, wherein the control block 220c is capable of transmitting the unique identification code to the main block 210 through the communication unit 220a when the control block 220c is connected to any one of the at least two coding blocks. The function block 224 may be connected last.

In addition, (b) to (e) of fig. 2b show diagrams of the appearances of various function blocks 220, where (b) may be a function block 221 for movement (forward or backward) of the device 300, (c) may be a function block 222 for rotation of the device 300, (d) may be a pair of function blocks 223 for repeated operation of the device 300, and (d) may be a function block 224 for termination.

In addition, in fig. 2b (b), reference numeral 221b corresponds to a selection switch for selecting forward or backward, reference numeral 221d corresponds to the display portion 220d, in fig. 2b (c), reference numeral 222b corresponds to a selection switch for selecting a rotation direction (clockwise or counterclockwise), and reference numeral 222d corresponds to the display portion 220 d. Similarly, in (d) of fig. 2b, reference numeral 223d corresponds to the display portion 220d, and in (e) of fig. 2b, reference numeral 224d also corresponds to the display portion 220 d.

The function block 220 is only an example for facilitating understanding of the present invention, and may be a block for performing other inherent functions of the device 300. For example, regarding operations, where the device 300 is a drone, the function block 220 may be a block for performing functions such as fly-up, fly-down, flip-right, etc.; in the case where the apparatus 300 is a robot, the function block 220 may be a block for performing an in-place jump, a forward jump, or the like. In addition, regarding the sound, the function block 220 may perform functions of playing a recorded sound, a greeting, making a cat-call, a laughter, a musical scale, etc., and in case of additionally providing an LED, the function block 220 may perform various functions of displaying a specific color, blinking a predetermined number of times in a specific color, or blinking at a speed, etc.

In addition, the storage block 250 may be a block in which the program code of the coding block and the unique identification code of the storage block 250 are stored in advance, or may be a block in which only the unique identification code of the storage block 250 is stored. The program code pre-stored in the storage block 250 may be at least one.

As shown in fig. 1 and 2e (a), the storage block 250 may include: a communication unit 250 a; a storage part 250b for storing the unique identification code and the program codes corresponding to the at least two encoding blocks 220; a control unit 250c that, when connected to any one of the at least two coding blocks 220 or the master block 210, is capable of transmitting the unique identification code and the program code corresponding to the at least one coding block 220 stored in the storage unit 250b to the master block 210 through the communication unit 250 a; and a display unit 250d for displaying the execution state of the memory block 250.

In fig. 2e (b), reference numeral 250d corresponds to the display unit 250 d.

In addition, according to another embodiment of the present invention, the storage block 250 may be configured to include: a communication unit 250 a; a storage section 250b for storing a unique identification code; a control part 250c capable of transmitting a unique identification code to the main block 210 through the communication part 250a when connected to any one of the at least two encoding blocks; the display unit 250d displays the execution state of the memory block 250.

The generation and storage process of the program code according to the above-described storage block 250 is explained as follows: at least one coding block is concatenated with the main block 210 and the storage block 250 is concatenated on the last coding block of the concatenation. Thereafter, when the total execution button 214a of the main block 210 is pressed, the unique identification code of the storage block 250 and the unique identification code of the at least one coding block connected to the main block 210 are transmitted to the main block 210, and the main block 210 can store the program code corresponding thereto in the storage part 212 of the main block 210 according to the unique identification code of the connected at least one coding block by referring to the storage part 212.

Alternatively, according to other embodiments of the present invention, at least one coding block is concatenated with the main block 210, and the storage block 250 is concatenated on the concatenated last coding block. Thereafter, when the total execution button 214a of the main block 210 is pressed, the unique identification code of the storage block 250 and the unique identification code of the at least one coding block connected to the main block 210 are transmitted to the main block 210, and the main block 210 can store the program code corresponding thereto in the storage part 212 of the storage block 250 according to the unique identification code of the connected at least one coding block by referring to the storage part 212.

In addition, the coding block assembly 200 according to an embodiment of the present invention may further include: a variable block 230 for storing the rotation angle, the movement distance, and the number of repetitions of the device 300; and a device block 240, the device block 240 being connectable only with the main block 210 and identifying devices operable through the coding block assembly 200.

First, fig. 2d is a block diagram of a variable block according to an embodiment of the present invention and a diagram showing an external appearance.

As shown in fig. 1 and 2d (a), the variable block 230 includes: a power supply 230 a; a load resistor (Rp)230b, one end of the load resistor (Rp)230b being connected to the power supply 230 a; a plurality of resistors (R1 to R9)230c having respective different resistance values; and a rotary switch 230d, wherein the rotary switch 230d is rotated in one direction such that the other end of the load resistor 230b is connected to any one of the plurality of resistors 230c, and the variable block 230 may be configured to output different voltages to the function block 220 according to the rotation angle of the rotary switch 230 d.

In addition, (b) to (c) of fig. 2d show the appearances of various variable blocks 230, (b) may be a variable block 231 associated with the moving (advancing or retreating) distance or the number of repetitions of the device 300, and (c) may be a variable block 232 associated with the rotation angle of the device 300.

That is, when the variable block 231 is connected to the function block 221 for movement (forward or backward) of the device 300, the variable block 231 outputs respective different voltages to the function block 221 according to different rotation angles (indicated by numbers corresponding to movement distances in table 3 below) of the rotary switch 230d, and the function block 221 may advance or retreat the device 300 by a preset distance based on the output voltages.

[ TABLE 3 ]

Is free of	1	2	3	4	5	6	7	8	R
										10cm	10cm	20cm	30cm	40cm	50cm	60cm	70cm	80cm	Random

In addition, when the variable block 231 is connected to the function block 223 for repeated operation of the device 300, the variable block 231 outputs respective different voltages to the function block 222 according to different rotation angles of the rotary switch 230d (indicated by numerals corresponding to the number of repetitions in the following table 4), and the function block 222 may repeatedly perform the operation of the device 300 based on the outputted voltages.

[ TABLE 4 ]

Is free of	1	2	3	4	5	6	7	8	R
										1 time of	1 time of	2 times (one time)	3 times of	4 times (twice)	5 times (twice)	6 times of	7 times (twice)	8 times (by volume)	Random

On the other hand, when the variable block 232 is connected to the function block 222 for rotation of the device 300, the variable block 232 outputs respective different voltages to the function block 222 according to different rotation angles (denoted by numerals corresponding to the rotation angles in the following table 5) of the rotation switch 230d, and the function block 222 may rotate the device 300 by a preset angle in a clockwise direction or a counterclockwise direction based on the output voltages.

[ TABLE 5 ]

When the

variable blocks

231 and 232 are not connected or when the number of the variable block is '0', the movement, repetition, or rotation may be performed at a set value (default movement distance is 10cm, default number of repetitions is 1, and default rotation angle is 45 degrees).

In table 6 below, the display states of the

display portions

220d, 250d of the above-described function block 220, storage block 250 are exemplarily described. The colors in table 6 are only helpful for understanding the present invention, and it is obvious to those skilled in the art that they may be changed to other colors.

[ TABLE 6 ]

In addition, fig. 2c is a block diagram of a device block according to an embodiment of the present invention and a diagram showing an external appearance.

As shown in fig. 1 and (a) of fig. 2c, the device block 240 may include: a communication unit 240 a; a storage part 240b for storing unique identification code information of the apparatus 300 capable of operating by encoding the block assembly 200; the control unit 240c can transmit the stored unique identification code information of the device to the main block 210 through the communication unit 240a when connecting to the main block 210.

At this time, when the unique identification code information of the device 300 received from the device block 240 does not coincide with the unique identification code information received from the device 300, the main block 210 may display an error through the display part 215 of the main block 210.

In addition, fig. 2c (b) shows the appearance of the device block 240.

The above-mentioned

blocks

210, 220, 230, 240, and 250 may be configured to be easily connected to each other by using a medium such as a magnet, and for the convenience of the visually impaired child, a positive letter and braille may be added on the surface of the

blocks

210, 220, 230, 240, and 250 to identify the

blocks

210, 220, 230, 240, and 250, thereby making a touch type teaching material.

In describing the present invention, any one of a wired communication module and a wireless communication module may be used for each constituent communication part, and the wireless communication module may include various communication modules such as bluetooth (bluetooth), wireless personal area network (zigbee), Radio Frequency Identification (RFID), wireless broadband (Wifi), and the like.

As described above, according to an embodiment of the present invention, various programming can be performed with a small number of blocks, and a part of a plurality of coding blocks can be executed, thereby having advantages of correcting errors and removing malfunctions. In addition, there is an advantage that it is possible to operate in a specific device by adding a device block.

In addition, fig. 3 is a flowchart illustrating a block type wireless coding command input method according to an embodiment of the present invention.

A block type wireless coding command input method according to an embodiment of the present invention will be described in detail with reference to fig. 1 to 3. However, in order to briefly and clearly explain the present invention, contents overlapping with those already explained in fig. 1 to 2e will be omitted.

The block type wireless coding command input method according to one embodiment of the present invention may be disclosed by a step of sequentially connecting at least two

coding blocks

220, 250 with a main block 210 to form a coding block assembly (S301).

As described above, according to an embodiment of the present invention, at least one of the at least two encoding

blocks

220, 250 may be a storage block 250 for controlling the operation of the apparatus based on stored program code.

As described above, at this time, the at least two encoding

blocks

220, 250 connected to the main block 210 respectively transmit the respective unique identification codes to the main block 210, and the main block 210 may refer to the storage part 212, generate a program code based on the unique identification codes of the at least two encoding blocks connected in sequence, and transmit the generated program code to the apparatus 300 (S302). However, it is possible for the storage block 250 to transmit only the unique identification code to the main block 210, or to transmit the unique identification code together with the program code corresponding to at least two encoding blocks stored in the storage section to the main block 210.

Finally, the apparatus 300 may perform an operation based on the received program code (S303).

As described above, according to an embodiment of the present invention, the main block 210 may transmit a total execution command or a staged execution command to the apparatus 300, at which time the apparatus 300 executes all program codes corresponding to at least two encoding blocks according to the total execution command, or the apparatus 300 stages a part of the program codes corresponding to at least two encoding blocks one by one each time a staged execution command is received.

As described above, according to an embodiment of the present invention, it is possible to perform various kinds of programming with a small number of blocks by using a memory block and to execute a part of encoded blocks among a plurality of encoded blocks, thereby having advantages of correcting errors and removing malfunctions. In addition, there is an advantage that it is possible to operate in a specific device by adding a device block.

A part of the method for training an encoding algorithm using an encoded block according to an embodiment of the present invention may be made into an application program for execution in a computer, and thus may be stored in a computer-readable medium. Examples of the computer readable medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage device. In addition, the computer-readable medium is dispersed in computer systems connected through a network, and thus the computer-readable code can be stored and executed in a dispersed manner. In addition, functional (function) programs, codes, and code segments for implementing the above methods can be easily derived by programmers skilled in the art of the present invention.

In the description of the present invention, the "unit" may be implemented in various forms such as a processor, a program command executed by the processor, a software module, microcode, a computer program product, a logic circuit, an application-specific integrated circuit, and firmware.

The scope of the present invention is not limited to the above-described embodiments and the drawings, and it will be apparent to those skilled in the art that the invention of the present invention is defined by the appended claims, and that the present invention may be variously replaced, modified and changed within a scope not departing from the technical idea of the present invention described in the claims.

Claims

1. A block-type wireless coded command input device, wherein the block-type wireless coded command input device comprises:

a master block; the coding block assembly comprises at least two coding blocks which are sequentially connected with the main block; and

a device for receiving program codes corresponding to at least two of the encoding blocks connected to a main block from the main block and performing an operation based on the received program codes,

at least one of the at least two coding blocks is,

a memory block for controlling the operation of the apparatus based on stored program code.

2. The block-type wireless coded command input apparatus of claim 1,

the main block transmits a staged execution command to the device each time an input of the staged execution command is received,

and the equipment sequentially executes a part of the program codes corresponding to at least two coding blocks one by one to eliminate the fault each time the staged execution command is received.

3. The block-type wireless coded command input apparatus of claim 1,

the block type wireless coding command input device further includes:

a device block connectable only to the main block and identifying devices operable through the coded block component.

4. The block-type wireless coded command input apparatus of claim 3,

the device block includes:

a communication unit;

a storage section for storing unique identification code information of a device operable by the encoding block assembly; and

a control section capable of transmitting the stored unique identification code information of the device to the master block through the communication section when the control section is connected to the master block;

the master block is capable of displaying an error when the unique identification code information of the device received from the device block is not identical to the unique identification code information of the device received from the device block.

5. The block-type wireless coded command input apparatus of claim 1,

the memory block includes:

a communication unit;

a storage section for storing a unique identification code and program codes corresponding to at least two encoding blocks;

a control unit capable of transmitting the unique identification code and the program codes corresponding to the at least two coding blocks stored in the storage unit to the master block through the communication unit when the control unit is connected to any one of the at least two coding blocks or the master block; and

a display section for displaying an execution state of the memory block.

6. The block-type wireless coded command input apparatus of claim 1,

the memory block includes:

a communication unit;

a storage section for storing a unique identification code;

a control unit capable of transmitting the unique identification code to the master block through the communication unit when the control unit is connected to any one of the at least two code blocks or the master block;

a display section for displaying an execution state of the memory block.

7. The block-type wireless coded command input apparatus of claim 1,

the coding block includes:

a function block having a unique identification code and for moving and rotating the device; a function block having a unique identification code and for repeating an operation of the apparatus; a function block having a unique identification code and used for termination; and the memory block for performing a function of at least one of the function blocks.

8. The block-type wireless coded command input apparatus of claim 1,

the main block includes:

a communication unit;

a storage unit configured to store unique identification codes of at least two of the encoding blocks and program codes corresponding to the unique identification codes;

a control section that generates a program code based on unique identification codes of at least two of the coding blocks sequentially connected to the main block by referring to the storage section, and transmits the generated program code to the device through the communication section;

an input section for receiving an input of a total execution command or a staged execution command of program codes corresponding to at least two of the encoding blocks; and

a display section for displaying an execution state of the program code in different colors,

the control section transmits the total execution command or the staged execution command to the device through the communication section,

the apparatus is capable of executing all of the program codes corresponding to at least two of the encoding blocks based on the total execution command, or the apparatus executes a part of the program codes corresponding to at least two of the encoding blocks one by one in stages each time the staged execution command is received.

9. A block type wireless coded command input method, wherein the block type wireless coded command input method comprises:

the method comprises the following steps that firstly, at least two coding blocks are sequentially connected with a main block to form a coding block assembly;

a second step of transmitting, in the coding block assembly, program codes corresponding to at least two of the coding blocks sequentially connected to the main block to a device; and

a third step of performing an operation based on the received program code in the apparatus;

wherein at least one of the at least two coding blocks is,