TWI426760B - Method for transmitting data between electronic devices - Google Patents

Description

Data transmission method between electronic devices

The present invention relates to a data transmission method for an electronic device, and more particularly to a method for performing data transmission by detecting collision between electronic devices.

When traditional handheld electronic devices use hands-free wireless transmission methods such as Bluetooth or Wi-Fi, it is usually necessary to make some settings to ensure that the data to be transmitted later is correctly Transfer to the other party. Due to confidentiality considerations, the above settings usually require cumbersome password confirmation and authentication steps to prevent data from being received by unrelated devices. However, these operations are inconvenient for the user.

The present invention provides a data transfer method for transferring data from one electronic device to another after the collision verification is passed.

In one embodiment, the data transmission method of the present invention is used in a first electronic device to transfer a data from a first electronic device to a second electronic device, wherein the first electronic device has a first sense of acceleration The data transmission method of the present invention includes: detecting, by the first acceleration sensor, a first electronic device and a second electronic device between the first electronic device and the second electronic device Collision; generating a first acceleration signal by the first acceleration sensor according to the detected collision, and transmitting the first acceleration signal to the first processing unit, wherein the first acceleration signal is a first time domain signal; The processing unit converts the first time domain signal into a first frequency domain signal; the first wireless signal transceiver module receives a second frequency domain signal by the second electronic device, wherein the second frequency domain signal is generated by the second electronic device Generating, according to the collision, the first processing unit to compare the first and second frequency domain signals; and when the correlation is greater than a predetermined value, the first electronic device transmits the data to the second Device.

According to the method of the present invention, the second electronic device has a second acceleration sensor, a second processing unit and a second wireless signal transceiving module. The second acceleration sensor is configured to detect a collision and generate a second acceleration signal according to the detected collision, wherein the second acceleration signal is a second time domain signal. The second processing unit is configured to convert the second time domain signal into a second frequency domain signal. The second wireless signal transceiver module is configured to transmit the second frequency domain signal to the first wireless signal transceiver module of the first electronic device.

According to the method of the present invention, the first timing unit of the first electronic device will record a first time data signal with respect to the time according to the collision record, and transmit the first time data signal to the first time. a processing unit; receiving, by the first wireless signal transceiver module, a second time data signal by the second electronic device, and transmitting the second time data signal to the first processing unit; and comparing the first and second time data signals by the first processing unit a time difference between; and when the correlation is greater than the predetermined value and the time difference is within a predetermined range, the first electronic device transmits the data to the second electronic device.

The method according to the present invention further includes: the first position detecting device of the first electronic device generates a first position coordinate data signal according to the geographical position coordinate of the first electronic device, and coordinates the first position coordinate Transmitting a data signal to the first processing unit; receiving, by the first wireless signal transceiver module, a second position coordinate data signal by the second electronic device, and transmitting the data to the first processing unit; and comparing the first processing unit by the first processing unit And a landmark difference between the second position coordinate data signal; and when the correlation is greater than the predetermined value and the coordinate difference is within a predetermined distance range, the first electronic device transmits the data to the second electronic device.

The method of the present invention further includes: receiving, by the first wireless signal transceiver module, a contact information signal by the second electronic device, and transmitting the information to the first processing unit, wherein the contact information signal includes a second contact data; Determining, by the first processing unit, whether a first contact person data stored in the first storage unit of the first electronic device matches the second contact person data; and when the relationship is greater than the predetermined value and the first contact person When the data matches the second contact data, the first electronic device transmits the data to the second electronic device.

The above and other objects, features, and advantages of the present invention will become more apparent from the accompanying drawings.

Referring to Fig. 1, there is shown a system 100 for implementing a data transfer method between electronic devices embodying the present invention. The system 100 includes a first electronic device 110 and a second electronic device 120. In the present invention, the electronic devices 110, 120 are electronic devices capable of collision contact, and may be accessories such as a mobile phone, a personal digital assistant, an MP3 player, a wireless keyboard, or a mobile phone. The first electronic device 110 includes a first wireless signal transceiver module 114, a first acceleration sensor 112, a first timing unit 118, a first position detecting device 116, and a first storage unit 119. Both are coupled to a first processing unit 117. Similarly, the second electronic device 120 includes a second wireless signal transceiver module 124, a second acceleration sensor 122, a second timing unit 128, a second position detecting device 126, and a second storage unit 129. The above components are all coupled to a second processing unit 127. In the present invention, the wireless signal transceiver module 114, 124 can be a Bluetooth module, a wireless area network (Wi-Fi) module or an infrared transceiver module, and the storage units 119, 129 can be Non-volatile memory, such as a hard disk or a flash memory.

Referring to Fig. 2, there is shown a flow chart of a method of transferring data between electronic devices in accordance with a first embodiment of the present invention. When the file data on the electronic device 110 is to be transmitted to the electronic device 120, the file data to be transmitted is selected on the electronic device 110 (step 202), such as photos, music, files, movies, etc., and then the electronic device The devices 110 and 120 collide (step 204). Since the electronic devices 110 and 120 generate acceleration during the collision, and are detected by the respective internal acceleration sensors 112 and 122, a first acceleration signal and a second acceleration signal are respectively generated and transmitted to the respective processes. Units 117, 127 (step 206). When the processing unit 127 of the electronic device 120 receives the second acceleration signal transmitted from the acceleration sensor 122, the second acceleration signal is transmitted to the electronic device 110 by the wireless signal transceiver module 124 (step 208). ). When the electronic device 110 receives the second acceleration signal from the electronic device 120 by its wireless signal transceiver module 114, it transmits it to its own processing unit 117, which compares its own first acceleration signal with the other party's first The two acceleration signals (step 210) and determine the correlation between the two, such as whether the similarity is greater than a predetermined value (step 212). If yes, it means that the verification passes, and the two electronic devices 110 and 120 have indeed collided with each other, and the data transfer can be started. Then, the wireless signal transceiver module 114 establishes a connection with the wireless signal transceiver module 124, so that the electronic device 110 transmits the file data to the electronic device 120 through the wireless signal transceiver module 114, and the electronic device 120 transmits and receives the wireless signal through the wireless signal transmitting and receiving module. Group 124 receives the archival material from electronic device 110 (step 214). If the result of the determination in step 212 is no, it indicates that the verification has not passed, and the archive data will not be transmitted between the electronic device 110 and the electronic device 120 (step 216).

Referring to Fig. 3, there is shown a flow chart of a method of transferring data between electronic devices in accordance with a second embodiment of the present invention. After the electronic devices 110, 120 collide with each other, the processing units 117, 127 receive the first and second acceleration signals transmitted from the acceleration sensors 112, 122, respectively. Since the acceleration sensors 112 and 122 also detect the acceleration generated during the non-collision, causing an error in verification, in this embodiment, after performing steps 202, 204, and 206, the processing units 117 and 127 may Separating the first and second acceleration signals respectively, or setting a threshold value to take several maximum collision waves, and then processing the processed first and second acceleration signals from the time domain Converting to the frequency domain to make the first frequency domain acceleration signal and the second frequency domain acceleration signal respectively, for example, performing Fast Fourier Transform (FFT) on the time domain acceleration signal to obtain frequency domain acceleration Signal (step 307). Then, the electronic device 120 transmits the second frequency domain acceleration signal to the electronic device 110 by using the wireless signal transceiver module 124 (step 308). When the electronic device 110 receives the second frequency domain acceleration signal from the electronic device 120 by its wireless signal transceiver module 114, it transmits it to its own processing unit 117, which compares its own first frequency domain acceleration signal. A second frequency domain acceleration signal with the other party (step 310), and determining the correlation of the two, such as whether the similarity is greater than a predetermined value (step 312). If yes, it means that the verification passes, and the two electronic devices 110 and 120 have indeed collided with each other, and the data transfer can be started. Then, the wireless signal transceiver module 114 establishes a connection with the wireless signal transceiver module 124, so that the electronic device 110 transmits the file data to the electronic device 120 through the wireless signal transceiver module 114, and the electronic device 120 transmits and receives the wireless signal through the wireless signal transmitting and receiving module. Group 124 receives the archival material from electronic device 110 (step 314). If the result of the determination in step 312 is no, it indicates that the verification has not passed, and the archive data will not be transmitted between the electronic device 110 and the electronic device 120 (step 316).

As described above, since the acceleration sensor 112 not only detects the acceleration generated during the collision, the acceleration generated by the electronic device 110, 120 during the movement is also detected by the acceleration sensor 112, thus The accuracy of determining whether the electronic device 110, 120 has experienced the same collision may be lowered. Therefore, in addition to the above-mentioned identification of the relationship between the time domain and the frequency domain acceleration signal, the present invention can also increase the comparison of other parameters to improve the accuracy of the judgment. According to the present invention, the timing units 118, 128 provided by the electronic devices 110, 120 record time, refer to Figures 4a and 5a, and after performing steps 202, 204, 206 or performing steps 202, 204, 206, 307, timing The units 108 and 208 respectively record a first time and a second time according to the collision, and respectively generate a first time data signal and a second time data signal with respect to the first and second time, and respectively transmit the same. To the processing units 117, 127 (step 432). The electronic device 120 then transmits the second time domain or frequency domain acceleration signal and the second time data signal to the first electronic device 110 by using the wireless signal transceiver module 124 (steps 434, 534). When the electronic device 110 receives the second time domain or frequency domain acceleration signal and the second time data signal from the electronic device 120 by the wireless signal transceiver module 114, it transmits the signal to its own processing unit 117. After verifying the acceleration correlation in the foregoing steps 210, 212 or 310, 312, the processing unit 117 further compares the time difference between the first and second time data signals, and determines whether the time difference is within a predetermined range. Internal (step 436). If yes, it means that the verification passes, and the two electronic devices 110 and 120 have indeed collided with each other, and the data transfer can be started. Then, the wireless signal transceiver module 114 establishes a connection with the wireless signal transceiver module 124, so that the electronic device 110 transmits the file data to the electronic device 120 through the wireless signal transceiver module 114, and the electronic device 120 transmits and receives the wireless signal through the wireless signal transmitting and receiving module. Group 124 receives the archival material from electronic device 110 (step 438). If the result of the determination in step 436 is no, it indicates that the verification has not passed, and the archive data will not be transmitted between the electronic device 110 and the electronic device 120 (step 216, step 316).

In addition, many mobile phones are equipped with Global Positioning System (GPS) receiving modules, which we can use for further verification. According to the present invention, the position detecting device 116 provided on the electronic device 110, 120, for example, the global positioning system receiving module or the Assisted Global Positioning System (AGPS) receiving module can be launched according to the artificial satellite. The signal calculates the current latitude and longitude of the electronic devices 110, 120. Referring to Figures 4b and 5b, after performing steps 202, 204, 206 or performing steps 202, 204, 206, 307, the position detecting devices 116, 126 will be generated according to the geographical position coordinates of the electronic devices 110, 120, respectively. A first position coordinate data signal and a second position coordinate data signal are transmitted to the processing units 117, 127, respectively (step 442). Then, the electronic device 120 transmits the second time domain or frequency domain acceleration signal and the second position coordinate data signal to the electronic device 110 by using the wireless signal transceiver module 124 (steps 444, 544). When the electronic device 110 receives the second time domain or frequency domain acceleration signal from the electronic device 120 and the second position coordinate data signal by the wireless signal transceiver module 114, it transmits the signal to its own processing unit 117. After verifying the acceleration correlation in the foregoing steps 210, 212 or 310, 312, the processing unit 117 further compares the coordinate difference between the first position coordinate data signal of the first position coordinate coordinate signal and the second position coordinate data signal of the other party, and It is determined whether the coordinate difference between the two is within a predetermined distance range (step 446). If yes, it means that the verification passes, and the two electronic devices 110 and 120 have indeed collided with each other, and the data transfer can be started. Then, the wireless signal transceiver module 114 establishes a connection with the wireless signal transceiver module 124, so that the electronic device 110 transmits the file data to the electronic device 120 through the wireless signal transceiver module 114, and the electronic device 120 transmits and receives the wireless signal through the wireless signal transmitting and receiving module. Group 124 receives the archival material from electronic device 110 (step 448). If the result of the determination in step 446 is no, it indicates that the verification has not passed, and the archive data will not be transmitted between the electronic device 110 and the electronic device 120 (step 216, step 316).

In addition, almost everyone's mobile phone stores contact information of relatives and friends, such as phone numbers, so that they can easily and quickly contact each other. Therefore, the mobile phone that each of the two parties who are familiar with each other has stored contact information may record the contact information of the other party's name, contact number, contact address or e-mail. Therefore, we can use this information for further verification. According to the present invention, the respective storage units 119, 129 of the electronic devices 110, 120 store the contact information of the holder, such as name, contact number, contact address or email. Referring to FIGS. 4c and 5c, after performing steps 202, 204, 206 or performing steps 202, 204, 206, and 307, the processing unit 127 of the electronic device 120 transmits the contact information by using the wireless signal transceiving module 124. The second contact data signal is transmitted to the electronic device 110 along with the second time domain or frequency domain acceleration signal (steps 454, 554). When the electronic device 110 receives the second time domain or frequency domain acceleration signal from the electronic device 120 and the second contact data signal by the wireless signal transceiver module 114, the electronic device 110 transmits the signal to its own processing unit 117. After the verification of the acceleration correlation in the foregoing steps 210, 212 or 310, 312, the processing unit 117 further compares whether the contact information in the second contact information signal transmitted from the electronic device 120 is recorded in the self storage. Some of the units 119 match the contact information (step 456). If yes, it means that the verification passes, and the two electronic devices 110 and 120 have indeed collided with each other, and the data transfer can be started. Then, the wireless signal transceiver module 114 establishes a connection with the wireless signal transceiver module 124, so that the electronic device 110 transmits the file data to the electronic device 120 through the wireless signal transceiver module 114, and the electronic device 120 transmits and receives the wireless signal through the wireless signal transmitting and receiving module. Group 124 receives the archival material from electronic device 110 (step 458). If the result of the determination in step 456 is no, it indicates that the verification has not passed, and the archive data will not be transmitted between the electronic device 110 and the electronic device 120 (step 216, step 316).

According to the method of the present invention, the time data signal, the position coordinate data signal, and the contact data signal can be transmitted by the wireless signal transceiver module along with the time domain or frequency domain acceleration signal. In addition, further comparison verification of time, location coordinates, and contact information may be performed alternatively or in combination. The data transfer is started when the comparison verification is performed. The order of comparison verification can be adjusted as needed, and there is no hard limit to the order of comparison.

According to the method of the present invention, the acceleration signal generated by the collision of the two electronic devices is used for comparison verification, and the cumbersome password confirmation step can be avoided. In addition, further comparisons of time, location coordinates, and contact information can enhance the accuracy of verification.

The present invention has been disclosed in the foregoing embodiments, and is not intended to limit the present invention. Any of the ordinary skill in the art to which the invention pertains can be modified and modified without departing from the spirit and scope of the invention. . Therefore, the scope of the invention is defined by the scope of the appended claims.

100. . . system

110. . . Electronic device

112. . . Acceleration sensor

114. . . Wireless signal transceiver module

116. . . Position detection device

117. . . Processing unit

118. . . Timing unit

119. . . Storage unit

120. . . Electronic device

120. . . Storage unit

122. . . Processing unit

124. . . Wireless signal transceiver module

126. . . Position detection device

127. . . Processing unit

128. . . Timing unit

129. . . Storage unit

202-554. . . step

Fig. 1 is a diagram showing a system for carrying out data transfer between electronic devices for carrying out the invention.

Figure 2 is a flow chart showing a method of performing data transfer between electronic devices according to the first embodiment of the present invention.

Figure 3 is a flow chart showing a method of performing data transfer between electronic devices in accordance with a second embodiment of the present invention.

Figure 4a is a flow diagram of a method of the first embodiment of the invention with further alignment verification of time data added.

Figure 4b is a flow diagram of a method of the first embodiment of the invention in which further alignment verification of position coordinate data is added.

Figure 4c is a flow diagram of a method of the first embodiment of the present invention with further comparison verification of contact information.

Figure 5a is a flow diagram of a method of a second embodiment of the invention in which further alignment verification of time data is added.

Figure 5b is a flow diagram of a method of a second embodiment of the invention in which further alignment verification of position coordinate data is added.

Figure 5c is a flow diagram of a method of the second embodiment of the present invention with further comparison verification of contact information.

202-316. . . step

Claims (9)

A data transmission method for a first electronic device to transmit a data from the first electronic device to a second electronic device, the first electronic device having a first acceleration sensor and a first processing a unit and a first wireless signal transceiving module, the method comprising: detecting, by the first acceleration sensor, a collision between the first electronic device and the second electronic device; a first acceleration signal generated by the first acceleration sensor and transmitted to the first processing unit, wherein the first acceleration signal is a first time domain signal; by the first processing unit Converting the first time domain signal into a first frequency domain signal; receiving, by the first wireless signal transceiver module, a second frequency domain signal by the second electronic device, wherein the second frequency domain signal is caused by the second The electronic device generates the data according to the collision; the first processing unit compares the first and the second frequency domain signals; and when the correlation is greater than a predetermined value, the first electronic device uses the data Transfer to this Two electronic devices. The method of claim 1, wherein the second electronic device has: a second acceleration sensor for detecting the collision, and generating a second acceleration according to the detected collision a signal, wherein the second acceleration signal is a second time domain signal; a second processing unit is configured to convert the second time domain signal into the second frequency domain signal; and a second wireless signal transceiver module And transmitting the second frequency domain signal to the first wireless signal transceiver module of the first electronic device. The method of claim 1, wherein the correlation between the first and second frequency domain accelerations is compared to the first and second frequency domain accelerations. The method of claim 1, wherein the first processing unit converts the first time domain signal into the first frequency domain signal by using a fast Fourier transform method. The method of claim 1, wherein the converting the first time domain signal into the first frequency domain signal by the first processing unit comprises: filtering the first acceleration signal. The method of claim 1, wherein the first electronic device further comprises a first timing unit, the method further comprising: the first timing unit will record a time according to the collision, and generate a time relative to the time a first time data signal, and the first time data signal is transmitted to the first processing unit; the first wireless signal transceiver module receives a second time data signal from the second electronic device, and transmits the The first processing unit: by the first processing unit comparing a time difference between the first and second time data signals; and when the correlation is greater than the predetermined value and the time difference is within a predetermined range The first electronic device transmits the data to the second electronic device. The method of claim 1, wherein the first electronic device further comprises a first position detecting device, the method further comprising: the first position detecting device is geographically based on the first electronic device a first position coordinate data signal is generated, and the first position coordinate data signal is transmitted to the first processing unit; and the first wireless signal transceiver module receives a second by the second electronic device Positioning the coordinate data signal to the first processing unit; wherein the first processing unit compares a landmark difference between the first and second location coordinate data signals; and when the correlation is greater than the predetermined value and the When the coordinate difference is within a predetermined distance range, the first electronic device transmits the data to the second electronic device. The method of claim 1, wherein the first electronic device further comprises a first storage unit, the first storage unit stores a first contact data, and the method further comprises: using the first wireless The signal receiving and receiving module receives a contact information signal from the second electronic device and transmits the information to the first processing unit, wherein the contact information signal includes a second contact data; the first processing unit determines the first contact Whether the person data is consistent with the second contact information; and when the relationship is greater than the predetermined value and the first contact information is consistent with the second contact data, the first electronic device transmits the data to the first Two electronic devices. The method of claim 7, wherein the first position detecting device is a global positioning system receiving module.