TWM473228U - Exercise coaching assistive device of muscle strength fitness equipment - Google Patents

Description

Exercise teaching aid for muscle fitness equipment

This creation is a kind of muscle fitness equipment design, especially a kind of exercise teaching aid for the user to correctly grasp the correct use steps, methods and correct posture of the strength fitness equipment when performing muscle strength training. Device.

However, this method must be limited to sending commands through traditional telephone lines, and it is not possible to remotely control or turn off remote control of various electrical appliances in the home via wireless or current Internet.

Due to the busyness of the modern industrial and commercial society and the increasing emphasis on appropriate sports, if you simply calculate the effectiveness of sports through the autonomous movement of the human body, there will be many shortcomings and areas to be strengthened, and there will be many people. Because of the incorrect method of exercise, there will be injuries and reduce people's interest in sports. In view of this, there are many practitioners who aim at people's habits, sports effects and sports to design a lot of people to do. Sports equipment that achieves the best exercise results for people to use.

However, in traditional muscle fitness equipment, the display only displays the user's exercise information, such as the number of times, weight, time, calories or total results after the end of the exercise, and does not show the correct use of the muscle fitness equipment, steps Or posture. Therefore, when using muscle strength training equipment for muscle strength training, users cannot know whether they are using the muscle strength fitness equipment, whether the steps are correct or the posture is correct, and they cannot understand the muscle strength fitness equipment. Whether the device position meets your height or arm length, etc. Physiological conditions, and the wrong use, steps and postures are easy for the user to cause sports injuries when using the muscle fitness equipment for muscle strength training, affecting the user's body, and unable to obtain muscle strength using the muscle fitness equipment. The sporting effect of training.

When using muscle strength equipment for muscle strength training, users often cannot know the correct use method, steps and correct posture of using muscle strength fitness equipment, and they cannot understand whether the equipment position of muscle strength fitness equipment meets their height. Or physiological conditions such as the length of the arm, but rely on the fitness instructor to guide the user in the side, to avoid the user's use of the muscle fitness equipment, the wrong use of the method, the steps and the wrong posture to cause physical injury to the user.

When using muscle strength equipment for muscle strength training, users need to be instructed by a fitness instructor to avoid sports injuries. Therefore, it is necessary to spend an additional amount to hire a fitness instructor to guide them. This is a burden.

Therefore, in view of the lack of traditional muscle fitness equipment, the main purpose of the present invention is to provide a sports teaching aid for muscle fitness equipment, which allows the user to exercise according to exercise when using muscle strength fitness equipment for muscle strength training. The auxiliary device adjusts its own usage, steps and posture.

The technical means used in the present invention to solve the problems of the prior art is to send a start signal to the microcontroller when the motion sensor senses one of the user's motion signals. When the microcontroller receives the start signal transmitted by the motion sensor, the microcontroller selects the sequence position adjustment step data and the sequence training step data display from the position adjustment step data memory device and the training step data memory device. The display is provided for the user to perform position adjustment and muscle strength training according to the sequence position adjustment step data and the sequence training step data displayed by the display in an automatic or manual control manner.

The operation unit can be used by the user to input a person verification code to the microcontroller. When the microcontroller receives the personal verification code of the user of the operation unit, the microcontroller uses the position adjustment step data storage device and the training step data memory device. According to the user's personal verification code, the individual sequence position adjustment step data and the sequence training step data are taken out to the display for the user to use as the basis and comparison of the gravity training. The microcontroller can be connected to a wireless device for the user to wirelessly transmit the personal verification code to the microcontroller.

In addition, the motion signal acquisition device can be used to capture the motion signal of the user during the muscle strength training using the muscle fitness device, and then the motion signal captured by the motion signal acquisition device is received by the image orientation comparison module. Comparing with the correct pose data in the correct pose database, when the motion signal does not match the correct pose data, at least one difference signal is generated.

Through the technical means adopted by this creation, the user can correctly use the muscle strength fitness equipment and correct posture when using the muscle strength fitness equipment for muscle strength training, and can grasp the muscle strength fitness in the process of performing the muscle strength training. Correct use of the device, steps and correct posture, to avoid sports injuries caused by incorrect use or incorrect posture during exercise, affecting the user's body. In addition, when using muscle strength fitness equipment for muscle strength training, the user does not need the coach to guide the side, reducing the user's overhead in performing muscle strength training.

The specific embodiments of the present invention will be further described by the following examples and accompanying drawings.

1‧‧‧Microcontroller

11‧‧‧ Human body signal wireless receiving interface

11a‧‧‧Device signal wireless receiving interface

2‧‧‧Display

3‧‧‧Operating unit

31‧‧‧Operation button set

32‧‧‧ touch device

3a‧‧‧Sports sensor

3b‧‧‧Portable electronic devices

4‧‧‧ Position adjustment step data memory device

41‧‧‧Sequence position adjustment steps

5‧‧‧ Training Step Data Memory Device

51‧‧‧Sequence training steps

6‧‧‧Sports signal acquisition device

61‧‧‧ camera

7‧‧‧Correct figure database

71‧‧‧Correct figure data

7a‧‧‧Correct figure database

71a‧‧‧ Data import and export

72a‧‧‧External memory device

8‧‧‧Figure comparison module

9‧‧‧ Human body signal sensor

91‧‧‧Wired transmission interface

92‧‧‧ Human body signal wireless transmission interface

9a‧‧‧Device signal sensor

91a‧‧‧Wired transmission interface

92a‧‧‧Device signal wireless transmission interface

9b‧‧‧Training weight adjustment device

9c‧‧‧Wireless ear hook body signal sensor

100‧‧‧Disc type counting device

101‧‧‧ dish

102‧‧‧First infrared emitting device

102a‧‧‧second infrared emitting device

102b‧‧‧First infrared transmitting and receiving device

102c‧‧‧second infrared transmitting and receiving device

103‧‧‧First infrared receiver

103a‧‧‧second infrared receiver

104‧‧‧First CD hole

104a‧‧‧Second disc hole

104b‧‧‧First disc reflection point

104c‧‧‧second disc reflection point

105‧‧‧First torus

106‧‧‧second torus

107‧‧‧Signal amplification circuit

108‧‧‧ Wave shaping circuit

S‧‧‧ operation signal

S1‧‧‧ start signal

S1a‧‧‧Automatic start signal

S2‧‧‧ sports signal

S3‧‧‧ difference signal

S4‧‧‧ Sports Information

S5‧‧‧ device signal

S6‧‧‧ Weight adjustment control signal

S7‧‧‧first infrared signal

S8‧‧‧second infrared signal

Sn‧‧‧ motion signal

K1‧‧‧Location Adjustment Step 1

K2‧‧‧Location Adjustment Step 2

K3‧‧‧Location Adjustment Step 3

Kn‧‧‧Location adjustment step n

K1’‧‧‧ Training Step 1

K2’‧‧‧ Training Step 2

K3’‧‧‧ Training Step 3

Kn’‧‧‧ training step n

L‧‧‧ drive belt

Θ1‧‧‧first phase difference

Θ2‧‧‧second phase difference

U‧‧‧Users

1 is a schematic diagram showing the circuit architecture of the first embodiment of the present creation; FIG. 2 is a sequence diagram showing the sequence position adjustment step of the first embodiment of the present creation; and FIG. 3 is a sequence training step showing the first embodiment of the present creation. FIG. 4 is a schematic diagram showing the circuit architecture of the second embodiment of the present invention; FIG. 5 is a schematic diagram showing the circuit architecture of the third embodiment of the present creation; and FIG. 6 is a schematic diagram showing the circuit architecture of the fourth embodiment of the present creation. Figure 7 is a schematic diagram showing the circuit architecture of the fifth embodiment of the present invention; Figure 8 is a schematic diagram showing the circuit architecture of the sixth embodiment of the present invention; and Figure 9 is a schematic diagram showing the circuit architecture of the seventh embodiment of the present invention; 10 is a schematic diagram showing the circuit architecture of the eighth embodiment of the present invention; FIG. 11 is a schematic diagram showing the circuit architecture of the ninth embodiment of the present invention; and FIG. 12 is a schematic diagram showing the circuit architecture of the tenth embodiment of the present creation; A schematic diagram of the circuit architecture of the eleventh embodiment of the present invention is shown; FIG. 14 is a schematic structural diagram showing the motion sensor of the present invention; and FIG. 15 shows a sense of motion of the present creation. One of the side views of the device; Figure 16 shows one of the schematic diagrams of the circuit structure of the present motion sensor; Figure 17 shows the structure of the creative motion sensor; Figure 18 shows the creation Figure 2 is a side view of the motion sensor; Figure 19 is a schematic diagram showing the circuit structure of the motion sensor; Figure 20 is a schematic view showing the human body sensor attached to the user's ear.

Please refer to FIG. 1 to FIG. 3 , wherein FIG. 1 is a schematic diagram showing the circuit structure of the first embodiment of the present creation, and FIG. 2 is a table showing the sequence position adjustment step of the first embodiment of the present creation, and FIG. 3 Displaying the sequence training steps of the first embodiment of the present creation Information sheet. As shown in the figure, the motion teaching assisting device of the present muscular fitness device comprises a microcontroller 1, a display 2, at least one operating unit 3, a motion sensor 3a, and a position adjusting step data memory device 4. And a training step data memory device 5. The display 2 is connected to the microcontroller 1.

The operation unit 3 is connected to the microcontroller 1 for a user to input an operation signal s to the operation unit 3, and then the operation unit 3 generates a start signal S1 to the microcontroller 1. A motion sensor 3a is connected to the microcontroller 1, and when the motion sensor 3a senses one of the user's motion signals Sn, an automatic start signal S1a is sent to the microcontroller 1. The motion sensor 3a is one of a disc type counting device, a reed sensing device or a Hall device.

The position adjustment step data storage device 4 is connected to the microcontroller 1. The position adjustment step data storage device 4 stores at least one sequence position adjustment step data 41, and the microcontroller 1 receives the automatic transmission from the motion sensor 3a. When the signal S1a is started, the sequence position adjustment step data 41 captured by the position adjustment step data memory device 4 is displayed on the display 2 by the microcontroller 1 for the user to understand and adjust the step information 41 according to the sequence position displayed by the display 2. Make position adjustments.

The microcontroller 1 captures the sequence position adjustment step data 41 from the position adjustment step data storage device 4, and sequentially adjusts the position adjustment steps K1 to Kn in the sequence position adjustment step data 41 and the corresponding position adjustment step text 1~ n. Position Adjustment Steps The patterns 1 to n are displayed on the display 2, and the user can perform position adjustment in an automatic or manual control manner according to the sequence position adjustment step data 41 displayed on the display 2.

The training step data storage device 5 is connected to the microcontroller 1. The training step data storage device 5 stores at least one set of sequence training step data 51, and the microcontroller 1 receives the automatic start transmitted by the motion sensor 3a. When the signal S1a is used by the microcontroller 1 The training sequence data step 51 is displayed on the display 2 by the training step data memory device 5 for the user to understand and perform the muscle strength training according to the sequence training step data 51 displayed on the display 2.

The microcontroller 1 retrieves the sequence training step data 51 from the training step data storage device 5, and sequentially sets the training steps K1'~Kn' in the sequence training step data 51 and the corresponding position training step characters 1~n, The training steps 1 to n are displayed on the display 2 for the user to perform the muscle strength training according to the sequence training step data 51 displayed on the display 2. Among them, the user can perform muscle strength training according to the training weight 1~n in the sequence training step information 51.

The microcontroller 1 retrieves the sequence training step data 51 from the training step data storage device 5, and sequentially performs the training steps K1~Kn in the sequence training step data 51 and the corresponding training step characters 1~n, training step diagram. Equations 1~n are displayed on the display 2 for the user to perform the muscle strength training according to the sequence training step data 51 displayed on the display 2.

Please refer to FIG. 4, which is a schematic diagram showing the circuit architecture of the second embodiment of the present creation. As shown in the figure, the motion teaching auxiliary device of the creative muscle fitness device further comprises a motion signal capturing device 6, a correct figure database 7 and a picture comparison module 8.

The motion signal capturing device 6 is connected to the microcontroller 1 for capturing the motion signal S2 of the user when using the muscle fitness device. The motion signal capturing device 6 includes a camera device 61 connected to the microcontroller 1 for capturing motion signal data of the user when using the muscle fitness device as the motion signal S2. The motion signal S2 includes one of the number, weight, time, and calorie value of the user when using the muscle fitness device, and the motion signal S2 is displayed on the display 2.

The correct pose database 7 is connected to the microcontroller 1 and has at least one correct pose data 71, and the pose comparison module 8 is connected to the microcontroller 1, the aspect ratio The module 8 receives the motion signal S2 captured by the motion signal acquisition device 6 and compares it with the correct pattern data 71 in the correct pattern database 7, when the motion signal S2 and the correct pattern data 71 are both If not, at least one difference signal S3 is generated.

Please refer to FIG. 5 and FIG. 6 , wherein FIG. 5 is a schematic diagram showing the circuit architecture of the third embodiment of the present creation, and FIG. 6 is a schematic diagram showing the circuit architecture of the fourth embodiment of the present creation. As shown in the figure, in an actual application, the operating unit 3 can select an operation button group having a plurality of operation keys (as shown in FIG. 4), or can be selected as a touch device 32 combined with the display 2 (eg, As shown in FIG. 5 , as the user operation unit, the operation unit 3 and the touch device 32 (as shown in FIG. 6 ) can be selected as the user operation unit to increase the user's use of the muscle fitness device. Convenience.

Please refer to FIG. 7, which is a schematic diagram showing the circuit architecture of the fifth embodiment of the present creation. As shown, the correct pose database 7a connects an add-on memory device 72a to the microcontroller 1 via a data input port 71a.

Please refer to FIG. 8 and FIG. 9 , wherein FIG. 8 is a schematic diagram showing the circuit architecture of the sixth embodiment of the present invention, and FIG. 9 is a schematic diagram showing the circuit architecture of the seventh embodiment of the present creation. As shown in the figure, the motion teaching auxiliary device of the creative muscle fitness device further includes at least one human body signal sensor 9 connected to the microcontroller 1 via a wired transmission interface 91 (such as a wire) for sensing use. At least one selected portion of the motion information S4, and the motion information S4 is transmitted to the microcontroller 1 (as shown in FIG. 8).

In practical applications, the human body signal sensor 9 can also transmit the motion information S4 to the microcontroller 1 via a human body signal wireless transmission interface 92 and a human body signal wireless receiving interface 11 (as shown in FIG. 9).

Please refer to FIG. 10 and FIG. 11 , wherein FIG. 10 is a schematic diagram showing the circuit structure of the eighth embodiment of the present creation, and FIG. 11 is a diagram showing the ninth embodiment of the present creation. Road architecture diagram. As shown in the figure, the motion teaching aid of the creative muscle fitness device further includes at least one device signal sensor 9a connected to the microcontroller 1 via a wired transmission interface 91a (such as a wire) for sensing the muscle. At least one device signal S5 of the fitness device, and transmits the device signal S5 to the microcontroller 1 (as shown in FIG. 9).

In a practical application, the device signal sensor 9a can also transmit the device signal S5 to the microcontroller 1 via a device signal wireless transmission interface 92a and a device signal wireless receiving interface 11a (as shown in FIG. 10).

Please refer to FIG. 12, which is a schematic diagram showing the circuit architecture of the tenth embodiment of the present creation. As shown in the figure, the exercise teaching aid of the creative muscle fitness device further includes a training weight adjusting device 9b connected to the microcontroller 1. At least one weight adjustment control signal S6 generated by the microcontroller 1 is output to the training weight adjustment device 9b for adjusting the weight of the muscle fitness device.

Referring to Fig. 13, there is shown a schematic diagram of the circuit architecture of the eleventh embodiment of the present invention. As shown in the figure, the motion teaching auxiliary device of the creative muscle fitness device further comprises a portable electronic device 3b connected to the microcontroller 1. The portable electronic device 3b transmits the personal verification code S to the microcontroller 1 in a wireless manner via a verification code wireless receiving interface 11b. The portable electronic device 3b is one of a smart mobile communication device, an electronic wristwatch, a tablet computer or an individual mobile action secretary (ipad).

Please refer to Fig. 14 to Fig. 16, wherein the 14th line shows one of the structural schematic diagrams of the present motion sensor, and the 15th line shows one of the side views of the present motion sensor, and the 16th figure shows One of the schematic diagrams of the circuit architecture of the motion sensor. As shown, the motion sensor 3a is a disc type counting device 100, and the disc type counting device 100 is coupled to a muscle strength fitness device and is rotated by a belt L of one of the muscle fitness devices. The disc type counting device 100 includes a disc body 101 and a first infrared emitting device 102. A first infrared receiving device 103, a second infrared emitting device 102a, and a second infrared receiving device 103a.

The disk body 101 is provided with a plurality of first optical disk holes 104 and a plurality of second optical disk holes 104a. The first infrared emitting device 102 and the first infrared receiving device 103 are respectively located on the first annular surface 105 and the second surface of the disk body 101. The annulus 106 corresponds to the first disc aperture 104. The second infrared ray emitting device 102a and the second infrared ray receiving device 103a are respectively located on the first annular surface 105 and the second annular surface 106 of the disk body 101 and correspond to the second optical disk hole 104a.

When the user uses the muscle fitness device and is in the forward rotation, the muscle fitness device drives the disc type counting device 100 to rotate, so that the first infrared receiving device 103 can receive the first of the first infrared emitting device 102 via the first optical disc hole 104. The infrared signal S7 is amplified by the signal amplifying circuit 107 and then subjected to signal processing by the waveform shaping circuit 108 to generate an automatic start signal S1a to the microcontroller 1.

When the user uses the muscle fitness device and is reversed, the muscle fitness device drives the disc type counting device 100 to rotate, so that the second infrared receiving device 103a can receive the second infrared emitting device 102a via the second optical disc hole 104a. The infrared signal S8 is amplified by the signal amplifying circuit 107 and then subjected to signal processing by the waveform shaping circuit 108 to generate an automatic start signal S1a to the microcontroller 1.

As can be seen from the above, the disc type counting device 100 can sense that the muscle strength fitness device is in a forward rotation state or a reverse rotation state when the muscle fitness device is rotated. Therefore, regardless of whether the muscle fitness device is in the forward rotation state or the reverse rotation state, the disc type counting device 100 can generate an automatic start signal S1a to the microcontroller 1 when the muscle fitness device is rotated.

Please refer to Figures 17 to 19, where Figure 17 shows the creative operation. The second schematic diagram of the structure of the motion sensor is shown in FIG. 18, which shows the second side view of the motion sensor of the present invention, and the 19th figure shows the second schematic diagram of the circuit structure of the motion sensor. As shown, the motion sensor 3b is a disc type counting device 100a, and the disc type counting device 100a is coupled to a muscle strength fitness device and is rotated by a belt L of one of the muscle fitness devices. The disc type counting device 100a includes a disc body 101, a first infrared ray transmitting and receiving device 102b, and a second infrared ray transmitting and receiving device 102c.

The disk body 101 is provided with a plurality of first optical disk reflection points 104b and a plurality of second optical disk reflection points 104c, and the first infrared light-emitting and receiving device 102b and the second infrared light-emitting and receiving device 102c are positioned adjacent to the disk body 101. Corresponding to the first disc reflection point 104b and the second disc reflection point 104c.

When the user uses the muscle fitness device and is in the forward rotation, the muscle fitness device drives the disc type counting device 100a to rotate by the belt L, and the first infrared transmitting and receiving device 102b emits a first infrared signal S7 to the first optical disc. After receiving the first infrared signal S7 reflected by the first optical disk reflection point 104b, the reflection point 104b repeatedly emits the first infrared signal S7 via a first phase difference θ1 and receives the reflected first infrared signal S7, and then The signal amplifying circuit 107 amplifies and then performs signal processing by the waveform shaping circuit 108 to generate an automatic start signal S1a to the microcontroller 1.

When the user uses the muscle fitness device and reverses, the muscle fitness device drives the disc type counting device 100a to rotate by the belt L, and the second infrared transmitting and receiving device 102c emits a second infrared signal S8 to the second disc. After receiving the second infrared signal S8 reflected by the second optical disk reflection point 104c, the reflection point 104c repeats the second infrared signal S8 and receives the reflected second infrared signal S8 through a second phase difference θ2, and then receives the reflected second infrared signal S8. After being amplified by the signal amplifying circuit 107, the signal processing is performed by the waveform shaping circuit 108 to generate an automatic start signal S1a to the microcontroller 1.

As can be seen from the above, the disc type counting device 100a can sense that the muscle strength fitness device is in the forward rotation state or the reverse rotation state when the muscle fitness device is rotated. Therefore, regardless of whether the muscle fitness device is in the forward rotation state or the reverse rotation state, the disc type counting device 100a can generate an automatic start signal S1a to the microcontroller 1 when the muscle fitness device is rotated.

Please refer to Fig. 20, which shows a schematic view of the present human body sensor attached to the user's ear. As shown in the figure, the human body signal sensor is designed as a wireless ear-hook body signal sensor 9c for wearing on the ear of the user U, by means of the wireless ear-hook body signal sensor 9c clip Hanging on the U ear of the user can detect the heartbeat signal of the user and transmit the heartbeat signal wirelessly.

The above-mentioned embodiments are only intended to illustrate the present invention and are not intended to limit the scope of the present invention. All other equivalent modifications or substitutions that have been made without departing from the spirit of the present invention should be included in the scope of the following claims. Inside.

1‧‧‧Microcontroller

2‧‧‧Display

3‧‧‧Operating unit

3a‧‧‧Sports sensor

4‧‧‧ Position adjustment step data memory device

41‧‧‧Sequence position adjustment steps

5‧‧‧ Training Step Data Memory Device

51‧‧‧Sequence training steps

S‧‧‧ operation signal

S1‧‧‧ start signal

S1a‧‧‧Automatic start signal

Sn‧‧‧ motion signal

Claims (17)

A motion teaching auxiliary device for a muscle fitness device includes: a microcontroller; a display connected to the microcontroller; at least one operating unit connected to the microcontroller for at least one activation by a user a start signal to the microcontroller; a position adjustment step data storage device connected to the microcontroller, storing at least one set of sequence position adjustment step data, the microcontroller receiving the transmission from the operation unit When the signal is started, the microcontroller adjusts the sequence position adjustment step data from the position adjustment step data storage device to display on the display; a training step data storage device is connected to the microcontroller and stores at least one group The sequence training step data, when the microcontroller receives the start signal transmitted by the operating unit, the microcontroller retrieves the sequence training step data from the training step data memory device and displays the data on the display. The motion teaching auxiliary device of the muscle fitness device according to claim 1, further comprising a motion sensor connected to the microcontroller for sensing an activity signal of the user, and sending an automatic start Start signal to the microcontroller. The motion teaching auxiliary device of the muscular fitness device according to the second aspect of the invention, wherein the motion sensor is a disc type counting device, and the disc type counting device comprises: a disc body coupled to the muscle force The fitness device is rotated by a driving belt of the muscle fitness device, the disk body having a first toroidal surface and a second toroidal surface, and a plurality of first optical disc holes and a plurality of second optical disc holes; a first infrared emitting device positioned on the first annular surface of the disk and corresponding to the first optical disk aperture; a first infrared receiving device is located on the second annular surface of the disk body and corresponds to the first infrared emitting device; a second infrared emitting device is located on the first annular surface of the disk body, and corresponds to The second infrared ray receiving device is located on the second annular surface of the disk body and corresponds to the second infrared ray emitting device; when the user uses the muscular fitness device and is in forward rotation The muscle fitness device drives the disc type counting device to rotate, so that the first infrared receiving device can receive the first infrared signal of the first infrared emitting device via the first optical disk hole, and then amplified by a signal amplifying circuit. Signal processing by a waveform shaping circuit to generate the automatic start signal to the microcontroller; when the user uses the muscle fitness device and reverses, the muscle fitness device drives the disc type counting device to rotate, so that The second infrared receiving device can receive a second infrared signal of the second infrared emitting device via the second optical disk hole, and the signal is amplified by the signal amplifying circuit. Shaped signal processing circuit, automatically generating the start signal to the microcontroller. The exercise teaching aid device of the muscle fitness device according to claim 3, wherein the disc type counting device comprises: a disc body coupled to the muscle fitness device, and the transmission belt of the muscle fitness device Driving the disk, the disk body is provided with a plurality of first disk reflection points and a plurality of second disk reflection points; a first infrared emission and receiving device is located adjacent to the disk body and corresponding to the first disk reflection a second infrared transmitting and receiving device located adjacent to the disk and corresponding to the second optical disk reflection point; When the user uses the muscle fitness device and is rotating forward, the muscle fitness device drives the disc type counting device to rotate by the driving belt, and the first infrared transmitting and receiving device transmits the first infrared signal to the first After the optical disk reflects the dot and receives the first infrared signal reflected by the reflection point of the first optical disk, the first infrared signal is repeatedly transmitted through a first phase difference and the reflected first infrared signal is received, and then The signal amplifying circuit amplifies and then performs signal processing by the waveform shaping circuit to generate the automatic start signal to the microcontroller; when the user uses the muscle fitness device and reverses, the muscle fitness device The driving belt drives the disc type counting device to rotate, and the second infrared emitting and receiving device transmits the second infrared signal to the second optical disc reflecting point and receives the second infrared signal reflected by the second optical disc reflecting point. Repetitively transmitting the second infrared signal after receiving a second phase difference and receiving the reflected second infrared signal, and then passing the letter After amplification circuit which performs signal processing by the waveform shaping circuit, automatically generating the start signal to the microcontroller. The motion teaching auxiliary device of the muscular fitness device according to claim 2, wherein the motion sensor is one of a disc type counting device, a reed sensor device or a Hall device. The motion teaching auxiliary device of the muscle fitness device according to claim 1, further comprising: a motion signal capturing device connected to the microcontroller for capturing the muscle strength of the user The motion signal of the fitness device; a correct figure database is connected to the microcontroller, and at least one correct picture data is built; a picture comparison module is connected to the microcontroller, and the figure is compared The module receives the motion signal captured by the motion signal acquisition device, and is in the correct pose database The correct pose data is compared, and when the motion signal does not match the correct pose data, at least one difference signal is generated. The motion teaching assisting device of the muscular fitness device according to claim 6, wherein the motion signal capturing device comprises a camera device connected to the microcontroller. The motion teaching auxiliary device of the muscular fitness device according to claim 6, wherein the correct figure database is built in connection with the microcontroller or connected to the external memory via a data input and output port. One of the devices. The exercise teaching aid of the muscle fitness device according to claim 6, wherein the motion signal includes one of a number, a weight, a time, and a calorie value of the user when using the muscle fitness device. The motion teaching auxiliary device of the muscular fitness device according to claim 1, wherein the operation unit comprises an operation button group having a plurality of operation keys or a touch connection to the microcontroller and combined with the touch of the display One of the control devices. The motion teaching auxiliary device of the muscle fitness device according to claim 1, further comprising at least one human body signal sensor connected to the microcontroller via one of a wired transmission interface or a wireless transmission interface, It is used to sense the human body signal of the user. The exercise teaching aid device of the muscle fitness device according to claim 11, wherein the human body signal sensor is a wireless earloop body signal sensor for measuring the heartbeat signal of the user. The motion teaching auxiliary device of the muscle fitness device according to claim 1, further comprising at least one device signal sensor connected to the microcontroller via one of a wired transmission interface or a wireless transmission interface, And sensing at least one device signal of the muscle fitness device and transmitting the device signal to the microcontroller. The exercise teaching auxiliary device of the muscle fitness device according to claim 1, further comprising a training weight adjusting device connected to the microcontroller, wherein the at least one weight adjustment control signal generated by the microcontroller is output to The training weight adjustment device. The motion teaching auxiliary device of the muscle fitness device according to claim 1, wherein the operation unit is configured for the user to input a person verification code to the microcontroller, and the microcontroller receives the operation unit to transmit When the personal verification code is output, the micro-controller retrieves the sequence position adjustment step data from the position adjustment step data storage device, and the micro-controller receives the transmission from the operation unit. When the personal verification code is used, the microcontroller retrieves the sequence training step data from the training step data storage device and displays the data on the display. The motion teaching auxiliary device of the muscle fitness device according to claim 15 , further comprising a portable electronic device connected to the microcontroller, and transmitting the personal verification code to the micro wirelessly Controller. The exercise teaching aid of the muscle fitness device according to claim 16, wherein the portable electronic device is one of a smart mobile communication device, an electronic wristwatch, a tablet computer or a personal action secretary.