JP2018527790A - Data transmission method and apparatus, and data reception method and apparatus - Google Patents

Abstract

The present invention relates to a data transmission method and apparatus, and a data reception method and apparatus. The data transmission method includes a step of determining a time parameter for transmitting current data, and 2N included in N-bit data according to the time parameter. Obtaining a correspondence relationship between different numerical values and time intervals, different time intervals corresponding to different numerical values, N ≧ 1, obtaining a current data bit string to be transmitted, and the data bit string On the other hand, the grouping is performed so that the data of each group becomes N bits, and the data of the group is indicated at the time interval corresponding to the numerical value of the data of each group according to the acquired correspondence relationship. , Including a step for transmitting the data of the group. [Selection] Figure 1

Description

Detailed Description of the Invention

This application claims priority based on the Chinese patent application whose application number is CN201501055517.8 and whose application date is September 21, 2015, and uses the whole of the said Chinese patent application for this application.

The present invention relates to the field of electronic technology, and more particularly, to a data transmission method and apparatus, and a data reception method and apparatus.

Currently, with rapid development of electronic products, external interfaces are becoming congested. Typical wired external interfaces include a USB interface and a DOCK interface. However, these interfaces require at least three or more wires for communication and charging, occupy a large volume in the electronic device, and require more hardware support. Therefore, in this technical field, in order to reduce the cost of hardware and the volume of electronic equipment, a two-line communication technology means that can realize data transmission using only two lines is desired.

The present invention is intended to solve one of the above problems. The present invention provides the following technical means.

According to a first aspect of the present invention, there is provided a data transmission method, which comprises determining a time parameter for transmitting current data, and according to the time parameter, 2 ^N pieces included in N-bit data. The time interval corresponding to the different numerical values, N ≧ 1, the step of acquiring the data bit string to be transmitted, and the data bit string On the other hand, the grouping is performed so that the data of each group becomes N bits, and the data of the group is indicated at the time interval corresponding to the numerical value of the data of each group based on the acquired correspondence relationship. Transmitting the group data.
In the data transmission method of the present invention, for each group of data, the step of transmitting the data of the group generates and transmits M signals, and the start time of each of the signals before the adjacent one A time interval between the start times of the two signals is a time interval corresponding to the numerical value of the data of the group, M ≧ 1, and M is a natural number.
In the data transmission method of the present invention, the step of generating the M signals includes a step of generating M low level pulses according to the time interval.
The data transmission method of the present invention further includes the steps of generating and transmitting K handshake signals before transmitting the first group of data, where K ≧ 2 and K is an integer.
The data transmission method of the present invention satisfies a preset relationship between the K handshake signals.
In the data transmission method of the present invention, the K handshake signals include a time parameter.
In the data transmission method of the present invention, the satisfaction of the preset relationship between the K handshake signals indicates that the preset relationship between the first time interval and the second time interval. The first time interval is a time interval between a start time of the i-th handshake signal and a start time of the i-1th handshake signal, and the second time The interval is the time interval between the start time of the i-th handshake signal and the start time of the (i + 1) -th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number.
The data transmission method of the present invention determines a first time interval group and / or a second time interval group based on the time parameter, and the first time interval group is at least one first time interval. And the second time interval group includes at least one of the second time intervals.
In the data transmission method of the present invention, the step of generating the K handshake signals includes the step of generating K low-level pulses according to the first time interval and the second time interval.
The data transmission method of the present invention includes a step of switching a currently used time parameter to a new time parameter according to a preset rule, and determining the new time parameter as a time parameter for transmitting current data; And updating the correspondence relationship based on the time parameter for transmitting the data and transmitting the data according to the updated correspondence relationship.

According to a second aspect of the present invention, there is provided a data receiving method, wherein the data receiving method includes determining a time parameter for transmitting current data, receiving X signals, and receiving X signals. Determining a time interval between each start time of two adjacent signals in the signal to obtain X-1 time intervals, where X is a positive integer and X>1; Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and a numerical value transmitted in the S time intervals. And the numerical value transmitted in S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data, and S> 1 If in S time intervals Interval are the same time, both X and S is a positive integer, and comprising the steps is S ≦ X-1, N ≧ 1, a.
The data receiving method according to the present invention may convert N-bit data based on the time parameter before obtaining a numerical value transmitted in the first consecutive S time intervals in the X-1 time intervals. It further includes a step of acquiring correspondence between 2 ^N different numerical values and time intervals included, and different time intervals corresponding to different numerical values.
In the data receiving method of the present invention, X-1 = n * S, n ≧ 1, and n is an integer.
In the data receiving method of the present invention, the step of receiving the X signals includes a step of detecting X low level pulses.
In the data receiving method of the present invention, before the step of receiving the X signals, the K signals are received, and it is detected whether or not a predetermined relationship is satisfied between the K signals. , K ≧ 2, and K is an integer.
In the data receiving method of the present invention, the step of determining a time parameter for transmitting the current data includes a step of determining a time parameter based on the K signals.
In the data receiving method of the present invention, the step of detecting whether or not the K signals satisfy a preset relationship includes detecting a time interval between the K signals, It is determined whether or not a predetermined relationship is satisfied between the time interval and the second time interval, and the first time interval corresponds to the start time of the i-th signal and the (i-1) -th time interval. A time interval between the start time of the signal and the second time interval is a time interval between the start time of the i-th signal and the start time of the (i + 1) -th signal, i = 2, 4,..., 2j, j = (K-1) / 2, K.gtoreq.3, and K is an odd number, and the relationship between the first time interval and the second time interval is preset. If X is satisfied, the method includes receiving the X signals.
In the data reception method of the present invention, the step of determining a time parameter based on the K signals determines a first time interval group and / or a second time interval group, and the first time interval group Includes at least one first time interval, and the second time interval group includes at least one second time interval, wherein the first time interval group and / or the second time interval group Determining the time parameter based on:
In the data receiving method of the present invention, the step of receiving the K signals includes a step of detecting K low level pulses.
The data reception method of the present invention switches a currently used time parameter to a new time parameter according to a preset rule, determines a new time parameter as a time parameter for transmitting current data, and the X signals , And determine the time interval between the start times of two adjacent signals in the X signals to obtain X-1 time intervals, where X is a positive integer and X> 1 and, based on a time parameter for transmitting current data, obtain a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals, and It gets a number that is transmitted in the time interval, the values are transmitted in the S time interval is a numerical value corresponding to discrete time intervals, contact numbers to ^the 2 ^N different numbers within the N-bit data That is one in the case of S> 1, comprising the step, each time interval is the same in the S time interval.
In the data receiving method of the present invention, the step of receiving the X signals includes receiving Y + 1 signals, removing noise in the Y + 1 signals, obtaining X signals, and Y + 1 ≧ X. Including the steps.

According to a third aspect of the present invention, there is provided a data transmission device, the data transmission device comprising: a time parameter determination unit for determining a time parameter for transmitting current data;
Based on the time parameter, it is for obtaining the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval, where the time intervals corresponding to the different numerical values are different and N ≧ 1 A time interval acquisition unit that is
A data bit string acquisition unit that acquires a data bit string of a current transmission target and performs grouping on the data bit string so that each group of data has N bits;
And a transmission unit for transmitting the data of the group so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group based on the acquired correspondence.
In the data transmission apparatus of the present invention, for each group of data, the transmission unit transmits the group data. The transmission unit generates and transmits M signals, and the start of each signal The time interval between the time and the start time of one adjacent previous signal is a time interval corresponding to the numerical value of the data of the group, including that M ≧ 1 and M is a natural number.
In the data transmitting apparatus of the present invention, the step of generating the M signals by the transmitting unit includes the transmitting unit generating M low level pulses based on the time interval.
The data transmission apparatus of the present invention further includes a handshake signal transmission unit for generating and transmitting K handshake signals, where K ≧ 2 and K is an integer.
The data transmission apparatus of the present invention satisfies a preset relationship between the K handshake signals.
In the data transmitting apparatus of the present invention, the K handshake signals include a time parameter.
In the data transmitting apparatus of the present invention, the satisfaction of the preset relationship between the K handshake signals indicates that the preset relationship between the first time interval and the second time interval. The first time interval is a time interval between a start time of the i-th handshake signal and a start time of the i-1th handshake signal, and the second time The interval is the time interval between the start time of the i-th handshake signal and the start time of the (i + 1) -th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number.
The data transmission device of the present invention is for determining a first time interval group and / or a second time interval group based on a time parameter, wherein the first time interval group is at least one of the first time interval groups. A handshake signal time interval determination unit that includes one time interval, and wherein the second time interval group includes at least one second time interval.
In the data transmitting apparatus of the present invention, the step of generating the K handshake signals by the handshake signal transmitting unit is performed K times by the handshake signal transmitting unit according to the first time interval and the second time interval. Generating a low level pulse.
The data transmission apparatus of the present invention switches a time parameter currently in use to a new time parameter according to a preset rule, determines the new time parameter as a time parameter for transmitting current data, and sets a time interval acquisition unit. A time parameter update unit for triggering to update the correspondence based on the new time parameter, a time interval acquisition unit for updating the correspondence based on the time parameter carrying the current data, and update And a transmission unit for transmitting data according to the corresponding relationship.

Further, according to a fourth aspect of the present invention, there is provided a data receiving device, the data receiving device comprising: a time parameter determining unit for determining a time parameter for transmitting current data;
Receiving X signals, determining a time interval between the start times of two adjacent signals in the X signals, and obtaining X-1 time intervals; Where X is a positive integer and X> 1, the receiving unit;
Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and a numerical value transmitted in the S time intervals. The numerical value transmitted in S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data. Yes, if S> 1, the data acquisition unit includes the same time interval in S time intervals.
The data receiving apparatus according to the present invention is based on the time parameter before the data acquisition unit acquires the numerical value transmitted in the first consecutive S time intervals in the X-1 time intervals. And a time interval acquisition unit for acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time intervals, and the time intervals corresponding to the different numerical values are different.
In the data receiving apparatus of the present invention, X−1 = n * S, n ≧ 1, and n is an integer.
In the data receiving apparatus of the present invention, receiving the X signals by the receiving unit includes detecting that the receiving unit has detected X low-level pulses.
The data receiving apparatus of the present invention further includes a handshake signal receiving unit for receiving K signals and detecting whether or not a predetermined relationship is satisfied between the K signals.
In the data receiving apparatus of the present invention, determining the time parameter for transmitting the current data by the time parameter determining unit includes determining the time parameter based on the K signals by the time parameter determining unit.
In the data receiving apparatus of the present invention, the handshake signal receiving unit receives the K signals, the handshake signal receiving unit detects a time interval between the K signals, and the first time interval is detected. And whether the first time interval satisfies the preset relationship between the first time interval and the second time interval, and the first time interval is the start time of the i-th signal and the start of the i-th signal. The second time interval is the time interval between the start time of the i-th signal and the start time of the (i + 1) -th signal, i = 2, 4,. ..., 2j, j = (K-1) / 2, K≥3, and K is an odd number, and the first time interval and the second time interval satisfy a preset relationship If not, the receiving unit is notified to perform the step of receiving X signals.
In the data receiving apparatus of the present invention, the time parameter determining unit determines the time parameter for transmitting the current data because the time parameter determining unit determines the first time interval group and / or the second time interval group. Determining, wherein the first time interval group includes at least one first time interval, the second time interval group includes at least one second time interval, and the first time interval group. And / or determining a time parameter based on the second time interval group.
In the data receiving apparatus of the present invention, the reception of the K signals by the handshake signal receiving unit includes that the handshake signal receiving unit has detected K low-level pulses.
A data receiving apparatus according to the present invention switches a time parameter currently in use to a new time parameter according to a preset rule, and determines a new time parameter as a time parameter for transmitting current data. Receiving X signals, determining a time interval between the start times of two adjacent signals in the X signals, and obtaining X-1 time intervals. However, based on the receiving unit where X is a positive integer and X> 1, and the time parameter for transmitting the current data obtained by the time parameter update unit, continuous in X-1 time intervals. A numerical value corresponding to an individual time interval for each of the S time intervals, and a numerical value transmitted in the S time intervals, Of a numerical value that is transmitted corresponds to each time interval in the time interval, the number is the one in ^the 2 ^N different numbers within N-bit data, when the S> 1, S number of time intervals And a data acquisition unit in which each time interval is the same.
The data receiving apparatus of the present invention further includes a filtering unit for receiving Y + 1 signals, removing noise in the Y + 1 signals, obtaining X signals and transmitting them to the receiving unit, Y + 1 ≧ X.

As can be seen from the technical means provided by the present invention described above, according to the technical means provided by the present invention, it is possible to transmit information using a transmission time interval, and the data transmission device can transmit between two signals. By indicating the data information transmitted in the time interval, data communication is possible only with two lines, and the data transmission device and the data reception device can communicate with only two communication interfaces.

Hereinafter, in order to explain the technical means according to the embodiments of the present invention more clearly, the drawings necessary for the description of the embodiments will be briefly described. Of course, the drawings in the following description are merely some embodiments of the present invention, and those skilled in the art can obtain other drawings from these drawings on the premise that they do not perform creative labor.

3 is a flowchart illustrating a data transmission method provided by Embodiment 1 of the present invention. It is a schematic diagram which shows the waveform which can respond | correspond to one time interval for every data group provided by Example 1 of this invention, and can respond also to several time intervals. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 2 provided by Example 1 of the present invention. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 1 provided by Example 1 of this invention. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 3 provided by Example 1 of this invention. 6 is a flowchart illustrating a data receiving method provided by Embodiment 2 of the present invention. It is a schematic diagram which shows the structure of the data transmitter provided by Example 3 of this invention. It is a schematic diagram which shows the structure of the data receiver provided by Example 4 of this invention. 7 is a flowchart illustrating a method for transmitting data with a new time parameter provided by Embodiment 5 of the present invention. 12 is a flowchart illustrating a method for transmitting data with another new time parameter provided by Embodiment 6 of the present invention. 12 is a flowchart illustrating a method for transmitting data with another new time parameter provided by Embodiment 7 of the present invention. 10 is a flowchart illustrating a method for transmitting data with another new time parameter provided by Embodiment 8 of the present invention. It is a schematic diagram which shows the structure of a data transmission system with the new time parameter provided by Example 9 of this invention. It is a flowchart which shows the data reception method provided by Example 10 of this invention. It is a flowchart which shows the data reception method provided by Example 11 of this invention. It is a schematic diagram which shows the structure of the data transmitter provided by Example 12 of this invention. It is a schematic diagram which shows the structure of the data transmitter provided by Example 13 of this invention. 18 is a flowchart illustrating a method for transmitting data provided by Embodiment 14 of the present invention. 18 is a flowchart illustrating another data transmission method provided by Embodiment 15 of the present invention. It is a schematic diagram which shows the structure of the data processor provided by Example 16 of this invention. It is a schematic diagram which shows the structure of another data processor provided by Example 17 of this invention.

DESCRIPTION OF EMBODIMENTS Hereinafter, technical means according to embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention. Of course, the described embodiments are merely some embodiments, not all embodiments. A person skilled in the art, based on the embodiments of the present invention, belongs to the protection scope of the present invention in any other embodiments obtained on the premise of not performing creative labor.

In the description of the present invention, “first” and “second” are only for the purpose of explaining the purpose, and are understood to mean to indicate / imply relative importance, quantity, and position. must not.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.

Example 1
According to the present embodiment, a data transmission method is provided. FIG. 1 is a flowchart of one data transmission method that can be selected in this embodiment. The execution subject in the embodiment of the present invention may be a transmitting end that transmits data.

As shown in FIG. 1, the data transmission method mainly includes the following steps 101 to 105.

Step 101: Determine a time parameter for transmitting current data.

In one selectable embodiment of the present example, the time parameter for transmitting the current data may be preset and determined in the data transmission end. Further, the data transmission end may be determined by obtaining from another device. Furthermore, the data transmission end may be calculated and determined by setting in advance. The present invention does not limit a method for determining a time parameter for transmitting current data. Finally, any method that can determine the time parameter for transmitting the current data belongs to the protection scope of the present invention.

In one selectable embodiment of the present example, this step is a selectable step.

Step 102, obtain the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval according to the time parameter. Here, the time intervals corresponding to different numerical values are different, and N ≧ 1.

As one selectable embodiment of the present embodiment, “correspondence between 2 ^N different numerical values included in N-bit data and time intervals is obtained according to the time parameter. Here, time intervals corresponding to different numerical values are obtained. May be understood as follows.

To obtain the corresponding relationship between the bit string and the time interval the 2 ^N length in a bit string is N, wherein, the 2 ^N bit strings are different from each other, different time interval corresponding to and different bit strings N ≧ 1. For example, when N = 1, each bit string in a bit string having two lengths of 1 is 0 and 1, respectively, and when N = 2, four bit strings having a length of 2 The bit strings in are respectively 00, 01, 10 and 11, and when N = 3 or 3 or more, it may be referred to the case where N = 2, so it will not be described in detail here.

In one selectable embodiment of the present embodiment, “2 ^N different numerical values included in N-bit data” may be understood as follows. For example, if the N = 1, 1-bit data includes 2 ¹ different numbers, 0, 1, respectively, if it is N = 2, 2-bit data includes 2 ^two different numbers, respectively 00, 01, 10, and 11. It may be understood as follows with respect to “obtaining correspondence between 2 ^N different numerical values included in N-bit data and time intervals according to the time parameter”. For example, when N = 1, a time interval corresponding to 0 is acquired according to the time parameter, and a time interval corresponding to 1 is acquired according to the time parameter. When N = 2, the time interval corresponding to 00 is acquired according to the time parameter, the time interval corresponding to 01 is acquired according to the time parameter, the time interval corresponding to 10 is acquired according to the time parameter, and the time A time interval corresponding to 11 is obtained according to the parameters. Of course, when N is another value, it is the same as the above understanding method, so it will not be described in detail here.

In one selectable embodiment of the present embodiment, the data transmission end can calculate the time interval corresponding to the numerical value by a calculation method agreed in advance with the data reception end. For example, when N = n, the calculation method of the time interval corresponding to the numerical value m may be as follows. That is, the time interval corresponding to the numerical value m = etu + m * pdt (where 0 ≦ m ≦ 2 ⁿ −1, etu is the first time parameter, and pdt is the second time parameter. For example, etu = 10 μs. , Pdt = 30 μs). That is, the calculation method of the time interval corresponding to the numerical value 11 may be 10 μs + 3 * 30 μs = 100 μs. With this selectable embodiment, a time interval corresponding to a numerical value can be calculated. Of course, the present invention may determine the time interval by other pre-agreed calculation methods, and the present invention is not limited thereto. By calculating a time interval corresponding to the numerical value by a calculation method agreed in advance, it is possible to ensure the scalability of data transmission. That is, regardless of what the value of N is, it is possible to calculate the correspondence between numerical values and time intervals that are different at the transmitting end and the receiving end.

As another selectable embodiment of the embodiment of the present invention, the data transmission end may determine a time interval corresponding to the numerical value according to a list previously agreed and stored with the data reception end. If the time interval corresponding to the numerical value is determined by querying the list, the efficiency of obtaining the time interval corresponding to the numerical value can be improved.

As another selectable embodiment of the embodiment of the present invention, the data transmission end calculates a time interval corresponding to the numerical value by a calculation method agreed in advance with the data reception end, and then the data transmission end. By referring to the list stored in advance, it is determined whether or not the time interval corresponding to the numerical value obtained by the calculation is within the reception range of the data receiving end. If the time interval corresponding to the numerical value is obtained by calculating the time interval corresponding to the numerical value and then obtaining the time interval corresponding to the numerical value by referring to the list, the expandability of the data transmission can be improved on the assumption that the receiving end normally receives.

Step 103: Acquire the current data bit string to be transmitted.

In one selectable embodiment of the present invention, the sending end of the data may itself generate the current transmission target data bit string or receive the current transmission target data bit string from another device. May be. The present invention is not limited to the current method of acquiring the data bit string to be transmitted. Finally, any method that can acquire the current data bit string to be transmitted belongs to the protection scope of the present invention.

As one selectable embodiment of the present invention, the data transmission end may be a single relay device that relays communication between the data reception end and another device (hereinafter referred to as a first terminal). . In this case, the data transmission end obtains a data bit string to be transmitted currently through a method including the following steps. In other words, step 103a receives the first data via the first interface. Step 103b, decoding the first data based on the protocol supported by the first interface to obtain the first data bit string to be transmitted. When the data transmission end is a relay device, it may have two communication interfaces. For example, it has a first interface and a second interface, the first interface is an interface that communicates with a first terminal, the second interface is an interface that communicates with a data receiving end, The interface may be an existing universal interface such as a USB interface, an audio interface, a serial port, Bluetooth, WiFi, NFC, or a wired interface, and receives the first data from the first terminal. Thus, you may connect to a 1st terminal via the said 1st interface. The first terminal may be a device such as a mobile phone, a computer, or a PAD. The first data may be data transmitted by a mobile phone, a computer, or a PAD. At the same time, depending on the interface type of the first interface, the first data received based on the supporting protocol may be decoded. For example, the first interface decodes the first data based on the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, the NFC protocol, etc., and a data bit string corresponding to the first data. To get. The data bit string is a first data bit string to be currently transmitted (that is, a data bit string to be currently transmitted). The second interface may be an interface connected to an electronic payment device (that is, a data receiving end), and transmits data to the electronic payment device via the second interface. The second interface may be a single TWI (Two-wire Interface) interface, and the electronic payment device can realize functions such as USB Key, OTP, and smart card. The present invention realizes converting data from a terminal into data suitable for communication with the data receiving end by performing data conversion via the first interface using the data transmitting end as a relay device. Thus, the conversion between different interfaces was realized, and the application range of the data transmission end of the present invention was expanded. When the data transmission end is a single relay device, the current transmission target data bit string is acquired via the first interface, and the current transmission is performed via the second interface by the data transmission method according to the present invention. The target data bit string may be transmitted. Of course, the transmitting end of the data according to the embodiment of the present invention uses the reception method described in the second embodiment described later to transmit X pieces of data in the receiving method described in the second embodiment described later via the second interface. A second data bit string corresponding to X-1 time intervals may be obtained by receiving a signal and by a numerical value corresponding to an individual time interval in the obtained S time intervals. According to a protocol supported by the first interface, the second data bit string is encoded to obtain the second data, and the second data is transmitted through the first interface. At this time, according to the interface type of the first interface, the second data bit string received by the supporting protocol is encoded. For example, the first interface may encode the second data bit string according to the USB protocol, audio protocol, serial port protocol, Bluetooth protocol, WiFi protocol, NFC protocol, etc. Get the data. Data conversion is performed via the first interface, and the data bit string generated in this embodiment is converted into data that can be supported by the universal interface protocol to realize conversion between different interfaces. The application range of the data transmission end of the embodiment was expanded.

Step 104: Group the data bit strings so that each group of data has N bits.

In this embodiment, step 103 and step 104 may be performed at any timing before step 102. Before transmitting data, the data bit string may be acquired and grouped. Further, the data transmission end may execute step 101 and step 102 once before transmitting data every time. Alternatively, the data transmission end first executes step 101 and step 102, and thereafter, every time data is transmitted, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained by step 102. Then, the current transmission target data may be encoded. Alternatively, setting one expiration date and transmitting data within the expiration date may be obtained by acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval in step 102, It is also possible to employ encoding for the data to be transmitted. Alternatively, each time an event trigger is received by means of event trigger, for example, the user inputs a time parameter for transmitting the current data, and 2 ^N different values and times contained in the N-bit data The correspondence of intervals is calculated once. This embodiment is not specifically limited.

As one selectable embodiment of the present invention, the data bit strings can be grouped in multiple ways so that each group of data is N bits. Grouping may be performed so that each group includes 1 bit, or grouping may be performed so that each group includes 2 bits. When the data bit string includes a singular number, grouping cannot be performed completely by a method including two bits. Therefore, the data bit string is supplemented with 0 and then grouped. At this time, the data transmission end and the data reception end are set or agreed in advance with respect to a method of supplementing 0. When transmitting a data bit string from the high order bits of data, the last bit of the bit string is supplemented with 0. Also, when transmitting a data bit string from the low order bits of data, 0 is supplemented to the high order bits of the bit string. Of course, when each group includes 3 bits and 3 bits or more, it is only necessary to refer to a method of grouping so that each group includes 2 bits.

Step 105: Based on the acquired correspondence relationship, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group.

In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of identical time intervals. For example, referring to FIG. 2, when data of one group includes 2 bits, the numerical value of the data of the group is 00, 01, 10 and 11, and the numerical value of the data of the group is 00, 1 The numerical value 00 is shown in one time interval, and at this time, the time length corresponding to the one time interval is etu. That is, the expression method of the data 00 of the group may be, for example, one time interval of 10 μs. When the data of the group is 00, a numerical value 00 may be indicated at five time intervals. At this time, the time length of each time interval in the five time intervals may be etu. That is, the expression method of the data 00 of the group may be a signal having five time intervals, and each time interval is a time interval of 10 μs. Employing the fact that the numerical value of each group of data corresponds to one time interval increases the data transmission speed and improves the efficiency. If it is adopted that the numerical values of the data of each group correspond to a plurality of time intervals, the numerical values corresponding to the time intervals can be accurately determined, and mistakes due to loss of the time intervals can be prevented during data transmission.

In one selectable embodiment of the present embodiment, when data of each group is transmitted, M signals are generated and transmitted. Among them, the time interval of the start time of one signal adjacent to the start time of each signal is a time interval corresponding to the numerical value of the data of the group, M ≧ 1, and M is a natural number. The time interval generated by adopting the signal is easy to detect and has an effect of high stability.

In addition, M signals may be generated by generating M low level pulses according to the time interval, or M signals may be generated by generating M high level pulses according to the time interval. Also good. The low level pulse / high level pulse may be a waveform that can distinguish the low level pulse / high level pulse by a rectangular wave, a sine wave, a triangular wave, or the like, but is not limited thereto. Preferably, a low level pulse is generated according to a time interval, and when the transmitting end and the receiving end communicate with each other, a method is adopted in which the transmitting end supplies power to the receiving end at a high level and transmits information with a low level pulse. A device adopting such a method can simultaneously perform power feeding and information transmission through the same line when performing information interaction, and thus the volume and cost of the device can be reduced.

In one selectable embodiment of the present example, before transmitting the first group data of step 105, the method further includes a step 105a of generating and transmitting K handshake signals. However, K ≧ 2 and K is an integer. Since only one time interval can be formed between two adjacent signals, at least two handshake signals must be generated and transmitted to indicate that there is at least one time interval. The transmitting end transmits a handshake signal, and the receiving end determines the data transmission start position based on the handshake signal, thereby improving the data transmission efficiency.

In addition, a preset relationship is satisfied among the K handshake signals. The transmitting end transmits a handshake signal that satisfies a preset relationship, and the receiving end can accurately determine whether or not the received data is a handshake signal based on the preset relationship.

In addition, a time parameter is included in the handshake signal. The receiving end obtains a time parameter by the K handshake signals, so that when the receiving end receives a signal from the transmitting end, the receiving end obtains a time interval, and data from the transmitting end according to the time parameter and the time interval. To get. Thereby, the receiving end can acquire the time interval indicating the numerical value of the data according to the time parameter used at the transmitting end, and the problem that the theoretical time parameter of the receiving end does not match the actual time parameter is solved.

In addition, the above-mentioned “satisfy a preset relationship between K handshake signals” means that a preset relationship is satisfied between the first time interval and the second time interval. There may be. Here, the first time interval is a time interval between the start time of the i-th handshake signal and the start time of the i-1th handshake signal, and the second time interval is the i-th handshake signal. Is the time interval between the start time of the first handshake signal and the start time of the (i + 1) th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3 and K is an odd number. In this selectable embodiment, “satisfying a preset relationship between the first time interval and the second time interval” is a relationship promised in advance by the transmitting end and the receiving end. For example, the second time interval is twice the first time interval. Whether the transmitting end transmits a handshake signal that satisfies a preset relationship, and whether the received signal is a handshake signal depending on whether the received data satisfies a preset relationship Judging. For example, when generating and transmitting five handshake signals, four time intervals t0, t1, t2, and t3 are included, where the first time interval includes t0 and t2, and the second time The interval may include t1 and t3. Further, the preset relationship in which the first time interval and the second time interval are satisfied may be t1 = 2t0 and t3 = 2t2.

In addition, by transmitting the time parameter in step 101 according to the time interval between the K handshake signals described above, the receiving end can obtain the time parameter used for the transmitting end by the K handshake signals, The time parameter used at the receiving end can be further confirmed. Specifically, the transmitting end may determine the first time interval group and the second time interval group according to the time parameter in step 101, the first time interval group including at least one first time interval, The two time interval groups include at least one second time interval.

In addition, K handshake signals are generated by generating K low level pulses at the first time interval and the second time interval. Alternatively, K handshake signals may be generated by generating K high-level pulses at the first time interval and the second time interval. As the low level pulse / high level pulse, a waveform capable of distinguishing the low level pulse / high level pulse from a rectangular wave, a sine wave, a triangular wave, or the like is shown, but the present invention is not limited thereto. Preferably, a handshake signal is generated by generating a low level pulse according to a time interval, and when the transmitting end and the receiving end communicate, the transmitting end feeds the receiving end at a high level and transmits information by a low level pulse. Adopt the method to do. A device adopting such a method can simultaneously perform power feeding and information transmission through the same line when performing information interaction, and thus the volume and cost of the device can be reduced.
As mentioned above, please refer to any of Examples 14 to 17 for details on how to send a handshake signal.

In one selectable embodiment of the present example, after step 105, the time parameter may be changed to satisfy the current rate of data transmission. That is, after step 105, in accordance with a preset rule, the currently used time parameter is switched to the new time parameter, the new time parameter is determined as the time parameter for transmitting the current data, and the current data is transmitted. The correspondence relationship may be updated according to the time parameter, and the data transmission may be further performed in the subsequent data transmission process based on the updated correspondence relationship. In this embodiment, the determination of the new time parameter may be completed through agreement between the transmitting end and the receiving end, or may be completed by querying a list of time parameters stored in advance by the transmitting end and the receiving end. Also good. For example, when sending a type of data, query the list to determine the time parameter that the type of data should use. The time parameter at the transmitting end is variable, and receiving ends with different data processing capabilities are matched, or different types of data are matched to further improve data processing efficiency. Specifically, refer to any of Examples 5 to 9.

In one selectable embodiment of this embodiment, after completing the transmission of the last group of data in step 105, the verification data is transmitted, and the verification data is used to transmit the data received by the data receiving end. A step 106 of determining completeness and accuracy may further be included. The verification data is verification data calculated by a verification method such as MAC verification, parity verification, or sum verification, but is not limited thereto.

In one selectable embodiment of the present example, after completing the transmission of the last group of data in step 105 or after completing the transmission of the last group of data in step 105, , Step 107 may further include a step 107 of transmitting A end signals (A ≧ 1 and an integer). The end signal may be the same as or different from the handshake signal. Based on the end signal, the receiving end can determine whether or not the reception of data has ended.

According to the technical means provided by the above-described embodiment of the present invention, the transmission end can indicate the data of the transmission waveform at the time interval of the transmission waveform, and the transmission of data can be completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking an example that the current bit string to be transmitted is 0011100100 and N = 2.

In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is a length of time occupied by data transmission. There is no correspondence between the number of time parameters and N, and it is only necessary to match the receiving end. The present embodiment is not limited to the specific number, as long as the time parameter can express the time interval corresponding to the numerical value of the data.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 2, the correspondence between four different numerical values included in the 2-bit data and the time interval is acquired according to the time parameter. That is, 00 = etu, 01 = etu + pdt, 10 = etu + 2 pdt, and 11 = etu + 3 pdt. In the present invention, a time interval corresponding to a numerical value of 2-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

In step 103, the current data bit string 0011100100 to be transmitted is acquired.

In step 104, the data bit string 0011100100 is grouped so that each group of data is 2 bits, that is, includes 00 11 10 01 00.

In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals. For example, 00 corresponds to a time interval of one etu (for example, 10 μs), and after one signal, another signal is transmitted at the time interval. The time length of the etu formed in this way indicates the numerical value 00. Of course, 00 may correspond to three etu time intervals (for example, each time interval is 10 μs), and after one signal, three signals are continuously transmitted and received at the etu time interval. If the end receives three such same time lengths, it is determined that the value 00 has been received. When the data of each group is shown at a plurality of the same time intervals, the number of time intervals may be the same at the transmitting end and the receiving end, but this embodiment is not specifically limited thereto.

In the present embodiment, the numerical value 00 is transmitted at the time interval of etu according to the order of the data bit strings. Indicates that the numerical value 11 is transmitted at the time interval of etu + 3 pdt, indicates that the numerical value 10 is transmitted at the time interval of etu + 2 pdt, indicates that the numerical value 01 is transmitted at the time interval of etu + pdt, and indicates the numerical value 00 at the time interval of etu. Indicates sending. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 3 as an example of one time interval corresponding to the numerical value of each group of data. The transmission of the data bit string is performed at the time interval between the signals. Complete.

Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking as an example that the current bit string to be transmitted is 0011100100 and N = 1.

In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. Since there is no correspondence between the number of time parameters and N, the present embodiment only needs to be able to express a time interval in which the time parameter corresponds to the numerical value of the data. Therefore, the number of time parameters is limited to a specific number of time parameters. do not do.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 1, the correspondence between two different numerical values included in 1-bit data and the time interval is acquired according to the time parameter. That is, 0 = etu and 1 = pdt may be used. In the present invention, a time interval corresponding to a numerical value of 1-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

In step 103, the current data bit string 0011100100 to be transmitted is acquired.

In step 104, the data bit string 0011100100 is grouped so that each group of data includes 1 bit, that is, 0 0 1 1 1 0 0 1 0 0, but this step may be omitted. .

In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals. For example, 0 corresponds to one etu time interval (for example, 10 μs), and after one signal, another one signal is transmitted at the time interval. The time length of the etu formed in this way shows the numerical value 0. Of course, 0 may correspond to three etu time intervals (for example, each time interval is 10 μs), and after one signal, three signals are continuously transmitted and received at the etu time interval. When the same three time lengths are received at the end, it is determined that the numerical value 0 is received.

In this embodiment, data of each group is transmitted according to the order of data bit strings. That is, the time interval of each signal is the time interval of etu, the time interval of etu, the time interval of pdt, the time interval of pdt, the time interval of pdt, the time interval of etu, the time interval of etu, the time interval of pdt, Time interval, etu time interval. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 4 by taking one time interval corresponding to the numerical value of the data of each group as an example, but the transmission of the data bit string is performed at the time interval between the signals. Complete.

Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking as an example that the current bit string to be transmitted is 0011100100 and N = 3.

In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. Since there is no correspondence between the number of time parameters and N, the present embodiment only needs to be able to express a time interval in which the time parameter corresponds to the numerical value of the data. Therefore, the number of time parameters is limited to a specific number of time parameters. do not do.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 3, the correspondence between eight different numerical values included in the 3-bit data and the time interval is acquired by the time parameter. For example, 000 = etu, 001 = etu + pdt, 010 = etu + 2 pdt, 011 = etu + 3 pdt, 100 = etu + 4 pdt, 101 = etu + 5 pdt, 110 = etu + 6 pdt, 111 = etu + 7 pdt. In the present invention, a time interval corresponding to a numerical value of 3-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

In step 103, the current data bit string 0011100100 to be transmitted is acquired.

In step 104, the data bit string 0011100100 is grouped so that each group of data is 3 bits. In this embodiment, when the acquired data bit string is not an integer multiple of the number of bits included in each group, an operation of supplementing 0 to the data bit string is performed. When the transmission order of the data bit string is changed from low-bid to high-order bit, the high-bit is supplemented with 0 to perform grouping to become 000 011 100 100, and the transmission order of the data bit string is changed from high-order bit to low-order bit Then, 0 is added to the low-order bits and grouping is performed to obtain 001 110 010 000.

In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In the present embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals.

In this embodiment, the data of each group is transmitted in the order from the low order bit to the high order bit of the data bit string. In other words, a signal having a time interval of etu + 4 pdt, a signal having a time interval of etu + 4 pdt, a signal having a time interval of etu + 3 pdt, and a signal having a time interval of etu are transmitted. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 5 by taking one time interval corresponding to the numerical value of the data of each group as an example, but the transmission of the data bit string is performed at the time interval between the signals. Complete. Of course, when data of each group is transmitted in the order from the high-order bit to the low-order bit, 0 may be supplemented to the low-order bit. The data transmission method is similar to the order from the low order bit to the high order bit. Since signals need only be sequentially transmitted according to a time interval corresponding to a numerical value starting from the high-order bit, it will not be described in detail here.

When N ≧ 4, data may be transmitted with reference to the data transmission method when N = 2 or N = 3.

When N = 1.5, data may be transmitted with reference to the data transmission method when N = 2, but there are differences as follows.

Corresponds to a numerical value in 3-bit data using at least two time intervals. That is, when the value of N is a non-integer, a plurality of time intervals are used to correspond to different numerical values in the B bit data. However, B is an integer multiple of N, and B is a positive integer.

Example 2
The present embodiment provides a data receiving method, and FIG. 6 is a flowchart of one selectable data receiving method of the present embodiment. The execution subject of the embodiment of the present invention may be a receiving end that receives data.

As shown in FIG. 6, the data receiving method mainly includes the following steps 201 to 203.

Step 201: Determine a time parameter for transmitting current data.

In one selectable embodiment of the present embodiment, the time parameter for transmitting the current data may be set and determined in advance at the data receiving end. Further, the data receiving end may be determined by obtaining from the transmitting end. Furthermore, the data receiving end may be calculated and determined by setting in advance. For example, the receiving end first receives a handshake signal before receiving data, and determines a time parameter for transmitting current data according to the handshake signal. It is not limited to the parameter determination method. Finally, any method that can determine the time parameter for transmitting the current data belongs to the protection scope of the present invention.

In one selectable embodiment of the present example, this step is a selectable step.

Step 202, receive X signals, determine a time interval between the start times of two adjacent signals in the X signals, and obtain X-1 time intervals. However, X is a positive integer and X> 1.

In one selectable embodiment of the present example, “receive X signals” may detect X low level pulses or X high level pulses. . As the low level pulse / high level pulse, a waveform capable of distinguishing the low level pulse / high level pulse from a rectangular wave, a sine wave, a triangular wave, or the like is shown, but the present invention is not limited thereto. Preferably, a low level pulse is detected. That is, when the transmitting end can provide a high level to the receiving end, a low level pulse is generated. When the transmitting end and the receiving end communicate with each other by such a method, the receiving end uses the high level from the transmitting end as a power source. The electric energy is provided to the electricity consuming member at the receiving end. For example, the receiving end is charged by a high level from the transmitting end, or a power source is not provided inside the receiving end, and the high level from the transmitting end is directly used as a power source. When a device adopting such a method performs information interaction, it can simultaneously perform power feeding and information reception through the same line, thereby reducing the volume and cost of the device.

In one selectable embodiment of the present example, prior to step 202, step 202a receives K signals and detects whether or not a predetermined relationship is satisfied between the K signals. Further included. However, K ≧ 2 and K is an integer. Since one time interval is formed only between two adjacent signals, at least two handshake signals should be received to obtain at least one time interval. The receiving end determines whether or not the K signals are handshake signals based on whether or not a predetermined relationship between the K signals is satisfied. The receiving end receives the handshake signal, determines the data transmission start position based on the handshake signal, and improves the data transmission efficiency.

In addition, in step 202a, a time interval between the K signals is detected, and it is determined whether or not the first time interval and the second time interval satisfy a preset relationship. Here, the first time interval is a time interval between the start time of the i-th signal and the start time of the (i-1) -th signal, and the second time interval is the start of the i-th signal. Time interval between the time and the start time of the (i + 1) th signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number . When the first time interval and the second time interval satisfy a preset relationship, a step of receiving X signals is executed. That is, it is determined that the received K signals are handshake signals, and the signals after the K signals are data transmission signals. Here, the value of K is provided in advance. Further, if the first time interval and the second time interval do not satisfy the preset relationship, the time interval between the subsequent K signals is detected, and the K number of times satisfying the preset relationship are detected. Before detecting a signal, it is determined whether or not a predetermined relationship is satisfied between the first time interval and the second time interval of the subsequent K signals. That is, when the handshake signal is not detected, the receiving end continues to detect the handshake signal and starts receiving data after detecting the handshake signal. As a result, it is possible to prevent a signal from being transmitted to the receiving end when there is an error operation at the transmitting end, and at the same time, it is possible to determine the start of data. Further, the preset relationship that satisfies the interval between the first time interval and the second time interval may be a relationship that the transmitting end and the receiving end promise in advance. For example, the second time interval is twice the first time interval. The receiving end determines whether or not the received signal is a handshake signal depending on whether or not the received data satisfies a preset relationship. For example, if five signals are received, it includes four time intervals t0, t1, t2 and t3, where the first time interval includes t0 and t2, and the second time interval includes t1 and t3. May be included. Further, the preset relationship in which the first time interval and the second time interval are satisfied may be t1 = 2t0 and t3 = 2t2.

Further, in step 202a, the received K signals further include a time parameter, and in step 201, the time parameter can be determined by the K signals. In addition, the first time interval group and the second time interval group are first determined, wherein the first time interval group includes at least one first time interval, and the second time interval group is at least One second time interval is included. Then, the time parameter is determined by the first time interval group and the second time interval group. For example, if the transmitting end transmits five handshake signals, and the first time interval t1 = etu and the second time interval t2 = etu + pdt, the receiving end depends on the first time interval and the second time interval. The values of the time parameters etu and pdt can be determined. By determining the time parameter based on the K signals, it is possible to prevent the theoretical time parameter at the receiving end from matching with the actual time parameter, and to ensure the accuracy of data transmission.

Similar to a signal transmitting data, the receiving end can detect that K signals have been received by detecting K low level pulses. Alternatively, K high-level pulses can be detected to determine that K signals have been received. The low level / high level pulse can be realized by a rectangular wave, a sine wave, or the like. Preferably, when a low level pulse is detected, that is, when the transmitting end provides a high level to the receiving end and K signals need to be transmitted, K low level pulses are generated to generate a transmitting end. When the receiving end communicates, a method is adopted in which the receiving end uses the high level from the transmitting end as a power source, or directly uses the high level of the transmitting end as a power source without providing a power source inside the receiving end. When a device using such a method performs information interaction, it can simultaneously perform power supply and information reception via the same line. Therefore, when performing information interaction that can reduce the volume and cost of the device, the device is connected via the same line. Thus, power supply and information reception can be performed simultaneously, so that the volume and cost of the device can be reduced.

The above description may refer to any one of Examples 14 to 17 regarding a specific mode in which K signals are received and a time parameter is acquired.

In one selectable embodiment of this example, receiving X signals means receiving Y + 1 signals, removing noise in Y + 1 signals, and obtaining X signals. Including. However, Y + 1 ≧ X. Specifically, any one of Examples 10 to 13 may be referred to.

According to the time parameter for transmitting the current data determined in step 203 and step 201, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, The numerical values transmitted in S time intervals are acquired, and the numerical values transmitted in S time intervals are numerical values corresponding to individual time intervals, and the numerical values are 2 ^N different numerical values included in N-bit data. Where S> 1, S time intervals are the same, X and S are both positive integers, and S ≦ X−1, N ≧ 1 . When S> 1 in X−1 time intervals, S consecutive time intervals are the same, and the value of N-bit data corresponding to each individual time interval is the number of S A numerical value transmitted in a time interval. For example, if seven signals are received, six time intervals are acquired, and three consecutive time intervals therein are the same. That is, the transmitting end indicates the numerical value of N-bit data at a plurality of the same time intervals, acquires N-bit data corresponding to individual time intervals among the three time intervals, and further transmits the N-bit data at three time intervals. A numerical value is acquired, and when S = 1, a numerical value transmitted in one time interval is acquired.

As an optional embodiment of an embodiment of the present invention, an individual for every successive S time intervals in X-1 time intervals, depending on the time parameter for transmitting the current data determined in step 201. A numerical value corresponding to each time interval is acquired, numerical values transmitted in S time intervals are acquired, and numerical values corresponding to individual time intervals are calculated and acquired by a plurality of calculation methods. For example, a numerical value corresponding to the time interval is obtained by a time interval of numerical value m = etu + m * pdt, which is a preset or agreed calculation method. For example, one time interval is received, and the numerical value of m is calculated and acquired by etu and pdt. For example, when m = 1, if the data of each group set or agreed in advance is 1 bit, the numerical value is 1, and if the data of each group is 2 bits, the numerical value is 01. If the data of each group is 3 bits, the numerical value is 001, and if the data of each group is 4 bits or 4 bits or more, the method of obtaining the numerical value is the same, and will be described in detail here. do not do.

According to one possible embodiment of an embodiment of the present invention, an individual time interval for each successive S time intervals in X-1 time intervals, depending on the time parameter for transmitting the determined current data. To obtain a numerical value transmitted in S time intervals (the numerical value is one of 2 ^N different numerical values included in the N-bit data, where S> 1 , S time intervals are the same, X and S are both positive integers, and S ≦ X−1, N ≧ 1) can be understood as follows.

According to the determined time parameter for transmitting the current data, a bit string corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and S time intervals are obtained. Get the bit string transmitted in. Here, if the numerical values transmitted in S time intervals are bit strings corresponding to individual time intervals, and S> 1, the S time intervals are the same, and S is a positive integer. And S ≦ X−1. For example, when X = 2 and S = 1, there is only one time interval, and a bit string corresponding to the time interval is acquired. When X is 3 or 3 and S = 1, a bit string having a plurality of time intervals and corresponding to each time interval is obtained. If X = 3 and S = 2, then there are two time intervals, the two time intervals are the same, and the time interval corresponds to one bit string, and the two time intervals are A bit string corresponding to one time interval is shown. If X is 5 or greater and 5 and S = 2, then it has 4 time intervals, one time interval in the previous two consecutive time intervals corresponds to one bit string, and later One time interval in two consecutive time intervals corresponds to one other bit string. That is, the previous two time intervals indicate one bit string, and the latter two time intervals indicate another bit string. Of course, the examples given above are exemplary, and any method capable of obtaining a bit string transmitted in S time intervals belongs to the protection scope of the present invention.

In one selectable embodiment of this example, before obtaining the numerical value transmitted in the first consecutive S time intervals in X-1 time intervals in step 203, the time parameter , Further includes a step 203 ′ of acquiring correspondence between 2 ^N different numerical values included in the N-bit data and time intervals. Here, the time intervals corresponding to different numerical values are different, and N ≧ 1. By determining a numerical value corresponding to the received time interval by calculating in advance 2 ^N different numerical values and time intervals included in the N-bit data, the decoding time after receiving the data can be further reduced. As one selectable embodiment of the embodiment of the present invention, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter (where time corresponding to the different numerical values is obtained). The interval is different and N ≧ 1) can be understood as follows. By the time parameter, 2 ^N pieces of length to obtain the corresponding relationship between the bit strings and time intervals in the bit string is N (where, 2 ^N bits string different from each other and corresponding to the different bit strings Time interval to be different and N ≧ 1).

In one selectable embodiment of the present embodiment, the embodiment does not include step 201. In this embodiment, “2 ^N different numerical values included in N-bit data and the correspondence relationship between time intervals are acquired. , Where the time intervals corresponding to different numbers are different ”is an essential step, i.e., if no time parameter determining the current data transmission is included, 2 ^N different numbers included in the N-bit data The correspondence between time intervals must be included.

In one selectable embodiment of the present embodiment, “2 ^N different numerical values included in N-bit data” can be understood as follows. For example, if the N = 1, comprises 2 to ¹ different numbers to 1-bit data is 0 and 1, respectively. If it is N = 2, it comprises ^{two two} different numbers within 2-bit data, respectively 00, 01, 10 and 11. “According to the time parameter, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired” can be understood as follows. For example, when N = 1, the time interval corresponding to 0 is acquired by the time parameter, and the time interval corresponding to 1 is acquired by the time parameter. When N = 2, the time interval corresponding to 00 is acquired by the time parameter, the time interval corresponding to 01 is acquired by the time parameter, the time interval corresponding to 10 is acquired by the time parameter, and the time The time interval corresponding to 11 is acquired by the parameter. Of course, when N is another value, it can be understood in the same manner as described above, so it will not be described in detail here.

In addition, the data receiving end calculates a time interval corresponding to the numerical value of the data by a calculation method set or agreed in advance with the data transmitting end. N = n, and the calculation method of the time interval corresponding to the numerical value m is the time interval corresponding to the numerical value m = etu + m * pdt (where 0 ≦ m ≦ 2 ⁿ −1, etu is the first time parameter) , Pdt is the second time parameter (for example, etu = 10 μs, pdt = 30 μs), ie, the time interval calculation method corresponding to the numerical value 11 is 10 μs + 3 * 30 μs = 100 μs, and this selectable implementation Depending on the form, the time interval corresponding to the numerical value can be calculated. Of course, the present invention may determine the time interval by other pre-agreed calculation methods. The present embodiment is not specifically limited to this. If the time interval corresponding to the numerical value is calculated by a calculation method agreed in advance, the expandability of data transmission can be ensured. That is, regardless of what the value of N is, the time interval corresponding to the numerical value of each data can be calculated at the transmitting end and the receiving end. The receiving end compares the calculated time interval with the received time interval, and can directly determine a numerical value corresponding to the time interval, thereby improving the efficiency of determining data.

As another selectable embodiment of the embodiment of the present invention, the data receiving end can determine the time interval corresponding to the numerical value by a list stored in advance by agreement with the data transmitting end. If the time interval corresponding to the numerical value is determined by the method of querying the list, the efficiency of obtaining the time interval corresponding to the numerical value can be improved.

In one selectable embodiment of this example, X−1 = n * S, n ≧ 1, and n is an integer. According to such a selectable embodiment, X signals can just transmit n * S data, and no problem arises that cannot be decoded by extra signals.

In one selectable embodiment of the present example, the time parameter can also be updated during data transmission. That is, after step 203, according to a preset rule, the currently used time parameter is replaced with a new time parameter, the new time parameter is determined as the time parameter for transmitting the current data, and X signals are received. Determine the time interval between the start times of two adjacent signals in X signals, obtain X-1 time intervals, and use the time parameter to transmit the current data Obtaining a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals, obtaining a numerical value transmitted in S time intervals, and is a numerical value numerical values transmitted corresponds to each time interval in the time interval, the number is the one in ^the 2 ^N different numbers within N-bit data, when the S> 1, S number of time intervals Further comprising the step 204 each time interval the definitive are identical. In this embodiment, the determination of a new time parameter may be completed by agreement between the transmitting end and the receiving end, or may be completed by querying a list of time parameters stored in advance by the transmitting end and the receiving end. Also good. For example, when sending a type of data, the list is queried to determine the time parameter that the type of data should use. The time parameter of the transmitting end is variable, and it can be matched with a receiving end having different data processing capabilities or different types of data, thereby further improving the efficiency of data processing. Specifically, refer to any of Examples 5 to 9.

In one selectable embodiment of the present example, after completing the reception of the last one data in step 203, the transmitting end transmits A end signals (A ≧ 1 and an integer). The receiving end can also receive A end signals. The end signal may be the same as the handshake signal or may be a signal in another specific format. The receiving end determines whether or not the reception of data is completed based on the end signal.

In one selectable embodiment of the present embodiment, after completion of reception of the last data in step 203 or after completion of reception of the last data, A end signals Before receiving the data, the receiving end can receive the verification data transmitted from the transmitting end, and the receiving end of the data determines whether the received data is complete and accurate based on the verification data. The verification data includes verification data calculated by a check method such as MAC verification, parity verification, or sum verification.

According to the technical means provided by the above-described embodiment of the present invention, the receiving end can determine the numerical value of the data of the received waveform according to the time interval of the received waveform, and can complete the data reception using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

As one selectable embodiment of the present invention, the data receiving end may be a single relay device that relays communication between the data transmitting end and another device (hereinafter referred to as the first terminal). . At this time, the data receiving end receives X signals through the second interface by the receiving method according to the present embodiment, and corresponds to the individual time intervals by the acquired S time intervals. To obtain a second data bit string corresponding to X-1 time intervals, and to encode the second data bit string according to a protocol supported by the first interface. The second data may be acquired and the second data may be transmitted via the first interface. At this time, according to the interface type of the first interface, the second data bit string received by the supporting protocol is encoded. For example, the first interface encodes the second data bit string according to the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, the NFC protocol, etc., and the second data to be transmitted now. To get. Data conversion is performed via the first interface, the data bit string generated in the present embodiment is converted into data that can be supported by the universal interface protocol, and conversion between different interfaces is realized. The application range of the receiving end of the example data has been expanded. Of course, when the data receiving end of the present invention is a relay device, it is also possible to receive the first data via the first interface, and the first data can be received by a protocol supported by the first interface. To obtain the first data bit string of the current transmission target, and after acquiring the data bit string of the current transmission target through the first interface, the first embodiment of the present invention The data bit string to be currently transmitted may be transmitted via the second interface by the data transmission method provided by the above. Further, when the data receiving end is a relay device, the data receiving end may have two communication interfaces. For example, the interface includes a first interface and a second interface, the first interface is an interface that communicates with the first terminal, and the second interface is an interface that communicates with a data transmission end. The first interface may be a conventional universal interface such as a wireless interface such as a USB interface, an audio interface, a serial port, Bluetooth, WiFi, or NFC, or a wired interface. You may connect to a 1st terminal via the said 1st interface, and may transmit 2nd data to a 1st terminal. The first terminal may be a device such as a mobile phone, a computer, or a PAD, and the second data may be data received by the mobile phone, the computer, or the PAD. At the same time, the received first data is decoded by the supporting protocol according to the interface type of the first interface. For example, the first interface decodes the first data according to the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, or the NFC protocol, and the data bit corresponding to the first data. The string may be acquired and transmitted via the second interface by the transmission method described in the first embodiment. The second interface may be an interface connected to an electronic payment device (ie, a data receiving end). Data may be transmitted to the electronic payment device via the second interface, and data transmitted from the electronic payment device via the second interface may be received. The second interface may be one TWI interface. The electronic payment device can realize functions such as USB Key, OTP, and smart card. Using the data reception end of the present invention as a relay device, data conversion can be performed via the first interface, and data from the data transmission end can be converted into data suitable for communication with the terminal.

Hereinafter, the data reception method provided by the embodiment of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 2.

In step 201, a time parameter for transmitting current data is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is the length of time occupied by data transmission. The number of time parameters does not have a corresponding relationship with N, and may simply be agreed upon with the transmitting end. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

In step 202, six signals are received and the time intervals between the start times of two adjacent signals in the six signals are determined to obtain five time intervals of etu, etu + 3pdt, etu + 2pdt, etu + pdt, etu. To do.

In step 203, 2-bit data corresponding to each of the above five time intervals is acquired. In the present embodiment, a numerical value corresponding to the time interval is acquired by a calculation method m = etu + m * pdt agreed in advance with the data transmission end. For example, if one time interval of 100 μs is acquired, m = 3 can be acquired. That is, the numerical value transmitted at the time interval is 11. Also, before this step, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter. For example, when N = 2, the correspondence between four different numerical values included in the 2-bit data and the time interval is acquired according to the time parameter. That is, 00 = etu, 01 = etu + pdt, 10 = etu + 2 pdt, and 11 = etu + 3 pdt are acquired. For example, when a time interval of 100 μs is received, it can be directly determined that the numerical value transmitted in the time interval is 11. Finally, reception of the bit string 0011100100 is completed.

In the present embodiment, the receiving end can indicate one group of data at one time interval in accordance with the transmission countermeasures at the transmitting end. For example, 00 is indicated at the time interval of only one etu, and the data transmission speed is increased. In addition, one group of data can be shown at a plurality of the same time intervals. For example, it indicates 00 at the time interval of three times of etu, so that the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

Hereinafter, the data reception method of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 1.

In step 201, a time parameter for transmitting current data is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. The number of time parameters has no correspondence with N. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

In step 202, 11 signals are received, and time intervals between the start times of two adjacent signals in the 11 signals are determined, and etu, etu, pdt, pdt, pdt, etu, etu, Ten time intervals of pdt, etu, etu are acquired.

In step 203, 1-bit data corresponding to each of the 10 time intervals described above is acquired, a numerical value 0 transmitted in the time interval of etu is acquired, a numerical value 0 transmitted in the time interval of etu is acquired, The numerical value 1 transmitted at the time interval of pdt is acquired, the numerical value 1 transmitted at the time interval of pdt is acquired,..., the numerical value 0 transmitted at the time interval of etu is acquired, and finally the bit string 0011100100 reception is completed.

In this embodiment, according to the transmission countermeasures at the transmission end, the reception end can indicate 1-bit data at one time interval. For example, 00 is indicated at the time interval of only one etu, and the data transmission speed is increased. In addition, 1-bit data can be indicated at a plurality of the same time intervals. For example, it indicates 00 at the time interval of three times of etu, so that the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

Hereinafter, the data reception method provided by the embodiment of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 3.

In step 201, the time parameter of the current transmission is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is the length of time occupied by data transmission. The number of time parameters does not have a corresponding relationship with N, and may simply be agreed upon with the transmitting end. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

In step 202, five signals are received, a time interval between the start times of two adjacent signals in the five signals is determined, and four time intervals of etu, etu + 3 pdt, etu + 4 pdt, etu + 4 pdt are obtained.

In step 203, 2-bit data corresponding to the four time intervals described above is acquired. In this embodiment, a numerical value corresponding to the time interval is obtained by a calculation method m = etu + m * pd agreed in advance with the data transmission end. For example, if one time interval of 100 μs is acquired, m = 3 can be acquired. That is, the data of the group is 101. Also, before this step, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter. For example, when N = 3, the correspondence between eight different numerical values included in the 3-bit data and the time interval is acquired by the time parameter. That is, 000 = etu, 001 = etu + pdt, 010 = etu + 2 pdt, 011 = etu + 3 pdt, 100 = etu + 4 pdt, 101 = etu + 5 pdt, 110 = etu + 6 pdt, 111 = etu + 7 pdt. For example, when a time interval of 100 μs is received, it can be directly determined that the numerical value of the data is 101. Finally, bits supplemented with 0 are deleted according to the number of data bits agreed in advance with the data transmission end, and reception of the bit string 0011100100 is completed.

In the present embodiment, the receiving end can indicate one group of data at one time interval in accordance with the transmission countermeasures at the transmitting end. For example, 000 is indicated at a time interval of one-time etu, and the data transmission speed is increased. In addition, one group of data can be shown at a plurality of the same time intervals. For example, 000 is indicated in the time interval of three times of etu, and the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

When N ≧ 4, the data can be received with reference to the data receiving method when N = 2 or N = 3, and will not be described in detail here.

Example 3
The present embodiment provides a data transmission apparatus. Since the apparatus corresponds to the data transmission method according to the first embodiment, it will not be described in detail, but will be described briefly here. For parts where the explanation is not clear, the first embodiment may be referred to.

In the present embodiment, the data transmission device may be a device such as a mobile phone, a computer, or a POS register.

FIG. 7 is a schematic diagram illustrating the configuration of one selectable data transmission apparatus according to the present embodiment. The apparatus mainly includes a time parameter determination unit 301, a time interval acquisition unit 302, a data bit string acquisition unit 303, and a transmission unit 304.

In this embodiment, the time parameter determination unit 301 is for determining a time parameter for transmitting current data. The time interval acquisition unit 302 is for acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval depending on the time parameter, and here, the time intervals corresponding to the different numerical values are different. N ≧ 1. The data bit string acquisition unit 303 is for acquiring a current data bit string to be transmitted and performing grouping on the data bit string so that each group of data has N bits. The transmission unit 304 is for transmitting the data of the group so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group based on the acquired correspondence.

In one selectable embodiment of the present invention, the transmission unit 304 transmitting the group data for each group of data includes the transmission unit 304 generating and transmitting M signals. . Here, the time interval between the start time of each signal and the start time of one adjacent signal is a time interval corresponding to the numerical value of the data in the group, M ≧ 1, and M is a natural number.

As one selectable embodiment of the present invention, the generation of M signals by the transmission unit 304 includes the transmission unit 304 generating M low level pulses over time intervals.

As one selectable embodiment of the invention, the data transmission device further comprises a handshake signal transmission unit 305 for generating and transmitting K handshake signals, where K ≧ 2 and K Is an integer.

In one selectable embodiment of the present invention, a preset relationship between the K handshake signals is satisfied.

In one selectable embodiment of the present invention, the K handshake signals include time parameters.

As one selectable embodiment of the present invention, satisfying the preset relationship between the K handshake signals is preset between the first time interval and the second time interval. Satisfying the relationship, wherein the first time interval is a time interval between the start time of the i th handshake signal and the start time of the i−1 handshake signal, and the second time The interval is a time interval between the start time of the i-th handshake signal and the start time of the (i + 1) -th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number.

As one selectable embodiment of the present invention, the data transmission device further comprises a handshake signal time interval determination unit 306 for determining the first time interval group and / or the second time interval group according to the time parameter. The first time interval group includes at least one first time interval, and the second time interval group includes at least one second time interval.

As one selectable embodiment of the present invention, the generation of K handshake signals by the handshake signal transmission unit 305 is performed K times by the handshake signal transmission unit 305 according to the first time interval and the second time interval. Generating a low level pulse.

As one selectable embodiment of the present invention, the data transmission device replaces the currently used time parameter with a new time parameter according to a preset rule, and the new time parameter transmits the current data. And a time parameter update unit 307 for triggering the time interval acquisition unit 302 to update the correspondence with the new time parameter, and a time interval for updating the correspondence with the time parameter for transmitting the current data It further includes an acquisition unit 302 and a transmission unit 304 for performing data transmission based on the updated correspondence.
In this example, it is used to determine the time parameter determination unit 301 and the time parameter of the current data transfer.
In the optional implementation method of the present embodiment, the current data transmission time parameter is designed in the data transmission device, but other devices after acquisition from the data transmission device are determined, and the data transmission device is deposited. The data transmission time parameter determination method that is not limited to this application and finalized after the calculation can be calculated in the above, the data transmission time parameter method should all belong for the time being as long as it can be finalized.
The time interval is for unit 302, the time is different from the 2N value included in the N-bit data parameter, and the time interval is different from the time interval for different numerical values.
Option implementation method as one of the embodiments, unit 302 for obtaining time in time interval Correspondence relationship of time interval different from 2N numerical value including N bit data, and different time interval corresponding to different numerical value N is the best:
The length of 2N acquisition is the correspondence between each bit bit skewer and the time interval in N. Among them, 2N bit skewer is different, and different from the time interval corresponding to different bit skewer, N is one. For example, each bit skewer in a bit with a length equal to 0 and 1, each bit bit skewer with a length of 1 in N = 1 ： 00, 01, 10 and 10, when N = san and above, reference N =
In the optional implementation method of this embodiment, 2N different numerical values including N bit data can be understood: for example, N = one hour, including one bit data, the 21 different numerical values are 0 and 1 respectively; N =, sometimes including bit data, the 22 types of numbers are 00.01, 11, and 11. 2 N different values of parameters including time in N-bit data and the correspondence between time intervals: For example, I N = Time is a time interval parameter corresponding to 0, Time is a corresponding time interval parameter; Is the time interval corresponding to the parameter, the time corresponding to the parameter interval corresponding to 00, the time corresponding to the time interval parameter corresponding to 01, the time corresponding to the parameter corresponding to the time interval, and the time corresponding to the parameter every time. Of course, when N takes other values, it is the same as the above understanding method, and will not be described here anymore.
In the optional implementation method of this embodiment, the time interval of the data transmission device adopts the time interval corresponding to the calculation method of the numerical calculation that should be negotiated between the unit 302 and the data reception device N = n time, Plan how to calculate the time interval corresponding to m for transmission data, time interval corresponding to numerical value = etu + m * pdt (in which 0 m ≤ ≤ 2n-1, etu is one time parameter, pdt second time parameter For example, etu = 10μs, pdt = 30μs), that is, the calculation method at the time interval corresponding to the numerical value is 10μs + 3 * 30μs = Hyakuμs is the time corresponding to the numerical value calculated by the same option implementation method interval. Of course, this application can be adopted, and there is a limit not to apply this application in the calculation method fixed time interval of the consultation in advance. In the time interval corresponding to the same numerical value for calculating the calculation method through prior consultation, the scalability of the transmission of guaranteed data, that is, how much N, the data transmission device and the data receiving device correspond to different numerical calculations and time intervals Relationship.
In this embodiment, another optional embodiment of the application, the time interval of the data transmission device is also adopted by the unit 302 and the data reception device is preliminarily determined as the consultation storage list, and the time interval corresponding to the same numerical value is adopted, The search list is more efficient at the time interval of this number time interval, so you can get better response to this value.
In this embodiment, another optional embodiment of the application, the data transmission device after the time interval corresponding to the calculation method of the numerical calculation should be negotiated with the unit 302 adoption of the time interval of the data transmission device The reception range of the reception data device whether or not the time interval belongs to the time interval corresponding to the data obtained by this calculation to determine the memory unit 302 search list in advance. After the time interval corresponding to the numerical calculation adopted, the search list method is further increased at the time interval corresponding to the numerical value, and the guarantee data receiving device also receives data normally, thereby enhancing the expandability of data transmission.
To obtain the data bit skew unit 303, currently waiting data bit skew, data bit skew grouping, one data N bits.
In the option implementation method of this application, the data bit skew generation unit 303 itself sends the data waiting for the time being, and the data bit skewer receives other data and other units of the data transmission equipment for the time being. As long as the bit skew acquisition method is limited to transmission, the current data can be finally obtained, and all the waiting transmission bit skew methods should belong to this protection scope.
The implementation method as an option of this application, the switching device as a data transmission device is a receiving device for data transfer communication with other devices (hereinafter referred to as the first terminal). Switch the data transmission device under the situation of the device, the data transmission device will send the transmission data bit for the time being as follows: first interface received first data; The first data bit skewer for decoding and transmission. Under the situation as a data transmission device switching device, there are two communication ports with data transmission devices, for example, the first interface and the second interface, the first interface the first and the terminal communication interface, the second interface Communicate with the data receiving interface. The first interface can be connected to wireless, wired interfaces such as USB interface, audio interface, serial interface, Bluetooth, wifi, NFC, etc. Data for the first time at the receiving terminal. The first terminal is a mobile phone, computer, PAD, etc. The first data is the data transmission required by the mobile phone, computer, PAD end. Also, depending on the first interface, the port type is different and decrypted with the first data received in the consultation of its own support, for example, USB consultation, audio consultation, serial consultation, Bluetooth protocol, wifi consultation, or NFC on the first interface The first data bit skewer (currently waiting to send data bit skewer) that waits for the data bit skewer corresponding to the data, which is decrypted with the first data, such as negotiations, and wins the first place. The interface of the electronic payment facility (that is, the data receiving device) connected to the second interface is the electronic payment facility from which the second interface data is transmitted. This second interface is a two-wire interface, which can realize this electronic payment facility such as USBkey function, OTP function and smart card function. The switching device that transmits and moves the data of this application can realize the first interface data conversion, and expanded the switching of the realized interface by the data of the received data communication to the conversion device to the data sent to the terminal Range of use of the data transmission device of this application. As a switching device to the data transmission device, the first interface can send the waiting transmission data bit skewer and the second interface can send the waiting transmission data bit skewer.
In this embodiment, the data bit skewer can be performed before the sending unit 304 data is transmitted by operating the execution bit skewer and the group when the data bit skewer arbitrarily collects data. Also, every time the data transmission device transmits data, the parameter determination unit 301 in the time, the time interval is obtained by the operation of the correspondence of the time interval different from the 2N numerical value including the N bit data to obtain the unit 302, or the data transmission The device is first time parameter determination unit 301, the time interval is operated by unit 302, the transmission data continues every time, the use includes time parameter determination unit 301, the acquisition unit 302 for operating the time interval, N bit data included Code the sent data corresponding to the correspondence of the time interval different from 2N numerical value; or the effective period of installation is to send the data within the effective period of the same as the data transmitting device. Acquire unit 302 N ratio to manipulate the interval code, especially for sending data corresponding to the correspondence of time interval different from 2N numerical value including data. Or, in the event trigger method, triggering from the first incident, for example, the correspondence of the time interval different from 2N numerical value including N bit data once input by the user and calculating the current data transmission time parameter. Specifically, this embodiment is not limited.
As an option of this application, adopting the implementation method, grouping data bit skewer unit 303 data bit skewer, adopting N bits for one data grouping various methods, Group special schemes, including grouping schemes, which can be adopted by each set. Under the circumstances of a single bit including a bit bit of a data bit, it is impossible to combine the bits completely, supplement the data bit skewer and divide 0 into groups. At this time, the data transmitting device and data receiving device are Set or negotiate complement 0 method, sometimes when sending data bit skew from high order from data, when bit skew is least significant complement 0, sometimes when sending data bit bit skew from low order from data, high order complement 0. Of course, if it is more than a bit including one, combine the method with each reference set of bits, and it is a luxury here.
Data group data of the same group that can be displayed at the time interval corresponding to the numerical value of each set of data for the shipping unit 304 by the correspondence of acquisition.
In the present embodiment, it can also correspond to a time interval that can correspond to one numerical data, and many same time intervals. Adopts accurate judgment at the time interval corresponding to the numerical value of each set of data, to prevent the numerical value corresponding to the same time interval, the error due to the lost time interval during the data transmission process.
In the optional implementation method of the present embodiment, when data is transmitted and one group database is transmitted, the transmission unit 304 can generate M signals, and one is adjacent to the beginning of all signals. The time interval at the start of the signal is the corresponding time interval, according to the number of numbers in this group, M is 1 and M is a natural number. The time interval generated by the signal method is detected and stable.
The time interval generation M degree low level pulse signal generation M method is transmitted to the option 304, the level pulse method M signal generation is high for the time interval M degree generation. The waveform display of high and low level pulses can be divided into square wave, positive wave, triangular wave, etc. that can adopt the same low level pulse / high level pulse, but this is not limited. Low-level pulse interval for priority adoption, high-level reception data device is supplied so that the data transmission device can be used at the time of data transmission device and data reception device communication, pulse information transmission through low-level method. By adopting this method of equipment, using a single line of information alternately, at the same time complete power supply and information transmission, the volume and manufacturing cost of the equipment that has become smaller.
In the optional implementation method of this embodiment, the handshake transmission unit 305 that also includes the data transmission device, the handshake signal generation unit 305, the transmission is K handshake signal, K is an integer and K is an integer. There is only an occurrence time interval between two adjacent signals, so at least an occurrence transmission signal that embodies two handshakes is at least one time interval. According to the data transmission device handshake signal transmission received data, the device is also updata transmission efficiency from the position of handshake signal judgment data transmission.
In optional locations, the setting relationship can be satisfied among K handshake signals. Data transmission device handshake transmission unit 305 shipping Satisfaction design related handshake, signal received data device also received the accurate determination of the design relationship received data is handshake signal.
Optional handshake, the signal includes the time parameter, the received data device can also shake the same time signal parameter, thereby sending the received data receiver to the transmitting side signal, the time through the time interval End from data sent parameters and time interval. In this system, data is sent by the receiving data device, and the parameters of the device are used in a time interval corresponding to the numerical value of the data.
Optionally, the design relationship between the K handshake signals above satisfies the first time interval and the second time interval design relationship, wherein the first time interval is the beginning of the i-th handshake signal. The time interval between the start times of the i-1th handshake signal and the start time of the i + 1th handshake signal is defined as i = N, 4 ..., 2j, j = (K-1) /, K is odd and K. In this option implementation method, a satisfactory design relationship between the 1-hour interval and the second-time interval is a promise relationship between any data transmission device and data-reception device in advance, for example, the second time interval is twice the first time interval. . A handshake signal is a design-related received signal that determines whether the data is received by the receiving device and the data is received by the receiving device. For example, if you send me a handshake signal, the time interval t0, t1, t2 and wine may include the first time interval, t0 and t2, the second time interval may include 1 and wine have a satisfying design relationship at the first and second time intervals: t1 = 2t0 wine = 2t2.
The option is still the data transmission time parameter in the time interval between the K handshake signals above, the receiver uses the same handshake signal as the data time parameter using the transmitter, and the confirmation data receiver uses the time parameter. . Specifically, the data transmission device also includes a signal interval determination unit including a handshake, the unit includes a parameter determination first time interval set and / or a second time interval set, and at least the first group including the first time interval according to time. At least one second time interval including a second time interval pair in the time interval.
Optionally, the handshake transmission unit 305 is a handshake signal with the following scheme being K: The handshake transmission unit 305 is the handshake signal with the first time interval and the second time interval being K times the low level pulse method is K times. The first time interval and the second time interval are K times high level pulse signal generation K handshake, low level pulse / high level pulse can be adopted, square wave, square wave, triangular wave etc. The waveform display of high and low level pulses is not limited. Priority adoption time interval When the low-level pulse format is a handshake signal, communication between the data transmission device and the data reception device, supply a high level reception data device so that the data transmission device can be used, pulse information transmission through the low-level method . By adopting this method of equipment, using a single line of information alternately, at the same time complete power supply and information transmission, the volume and manufacturing cost of the equipment that has become smaller.
As mentioned above, please refer to any of Examples 14 to 17 for details on how to send a handshake signal.
In the optional implementation scheme of this embodiment, the data transmission device to meet the current data transmission rate includes: the time parameter unit 306 is updated and the default rule is that the new time parameter to replace the current usage time parameter is new. Parameter data transmission time parameter for the time being; the unit 302 parameter update correspondence relationship for the trigger time interval according to the new time; the time interval unit 302, the data transmission time parameter update correspondence relationship for the time being used; the transmission unit 304, after the update Data transmission using correspondence. In this implementation plan, the data transmission device and the data reception device are completed through the determination of the new time parameter. Parameter of time when data should be used for table type data. The time parameter of the data transmission device can be changed precisely, the data processing capacity of the data receiving device, or a different type of data, improve the data processing efficiency. Specifically, refer to any of Examples 5 to 9.
In the optional implementation method of the present embodiment, the inspection data transmission unit 307 including the data transmission device, the sending unit 304 after completion of the last group data transmission, the inspection data transmission unit 307 shipping inspection data, the inspection data, the data reception Receive data to determine if the device is also completely correct. Inspection data calculated using a parity check such as MAC check, parity, or take or check, including but not limited to check data.
In the optional implementation method of this embodiment, the data transmission device includes: end transmission unit 308, after transmitting the last group data of the sending unit 304 to the same unit, or after transmitting the inspection data transmission unit 307 completion inspection data and transmitting A (A is an integer) is the end signal, and the same handshake signal as the clear signal is also different. This end signal allows the data receiving device to determine whether or not data reception is complete.

According to the technical means provided by the above-described embodiment of the present invention, the data transmission apparatus can indicate the data of the transmission waveform at the time interval of the transmission waveform, and the transmission of the data is completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

Example 4
The present embodiment provides a data receiving apparatus. Since the apparatus corresponds to the data receiving method according to the second embodiment, it will not be described in detail, but will be described briefly here. For parts where the explanation is not clear, the second embodiment may be referred to.

In this embodiment, the data receiving device may be an electronic payment device having device functions such as a smart card, a smart key device, and a dynamic password, and is used in combination with the data transmitting device in the third embodiment.

FIG. 8 is a schematic diagram showing a configuration of one selectable data receiving apparatus according to the present embodiment. The apparatus includes a time parameter determination unit 401, a reception unit 403, and a data acquisition unit 404.

In this embodiment, the time parameter determination unit 401 is for determining a time parameter for transmitting current data. The receiving unit 403 receives X signals, determines a time interval between the start times of two adjacent signals in the X signals, and acquires X-1 time intervals. Yes, where X is a positive integer and X> 1. The data acquisition unit 404 acquires a numerical value corresponding to an individual time interval for each successive S time intervals in the X−1 time intervals based on the determined time parameter, The numerical value transmitted in the interval is obtained, the numerical value transmitted in the S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is included in 2 ^N pieces of data included in the N-bit data. It is one of the different numerical values. Here, when S> 1, each time interval in the S time intervals is the same.

In one selectable embodiment of the present invention, the data receiving device is for the data acquisition unit to acquire a numerical value transmitted in the first consecutive S time intervals in X-1 time intervals. In addition, a time interval acquisition unit 402 is further included for acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval according to the time parameter. Here, the time intervals corresponding to different numerical values are different.

In one selectable embodiment of the invention, X-1 = n * S, n ≧ 1, and n is an integer.

In one selectable embodiment of the present invention, receiving unit 403 receiving X signals includes detecting unit 403 detecting X low level pulses.

In one selectable embodiment of the present invention, the data receiving apparatus receives K signals and detects whether or not the K signals satisfy a preset relationship. A signal receiving unit 405 is further provided.

In one selectable embodiment of the invention, determining the time parameter for which the time parameter determining unit 401 transmits the current data means that the time parameter determining unit 401 determines the time parameter according to K signals. Including.

In one selectable embodiment of the present invention, when the handshake signal receiving unit 405 receives the K signals, the handshake signal receiving unit 405 detects the time interval between the K signals, It is determined whether or not a predetermined relationship is satisfied between the first time interval and the second time interval, and the first time interval corresponds to the start time of the i th signal and the (i−1) th time. And the second time interval is the time interval between the start time of the i-th signal and the start time of the (i + 1) -th signal, and i = 2,4. ,..., 2j, j = (K-1) / 2, K ≧ 3, and K is an odd number, and a predetermined relationship is satisfied between the first time interval and the second time interval , Notifying the receiving unit to perform the step of receiving X signals.

In one selectable embodiment of the present invention, the time parameter determination unit 401 determines the time parameter for transmitting the current data so that the time parameter determination unit 401 can use the first time interval group and / or the second time. Determining an interval group, wherein the first time interval group includes at least one first time interval, the second time interval group includes at least one second time interval, and the first time interval group and / or Or determining a time parameter by a second time interval group.

In one selectable embodiment of the present invention, the handshake signal receiving unit 405 receiving the K signals includes the handshake signal receiving unit detecting K low level pulses.

In one selectable embodiment of the invention, according to a preset rule, the time parameter currently in use is replaced by a new time parameter, and the new time parameter is determined as the time parameter for transmitting the current data. Time parameter update unit 406 and X signals are received, and a time interval between the start times of two adjacent signals in X signals is determined to obtain X-1 time intervals. X-1 time, depending on the receiving unit for which X is a positive integer and X> 1, and the time parameter for transmitting the current data obtained by the time parameter update unit. Obtaining a numerical value corresponding to an individual time interval for each successive S time intervals in the interval, and obtaining a numerical value transmitted in S time intervals Tokusuru A data acquisition unit is a numerical value numerical value transmitted in the S time intervals corresponding to each time interval, the number is the one in ^the 2 ^N different numbers within N-bit data, wherein In the case of S> 1, it further includes a data acquisition unit in which each time interval in the S time intervals is the same.

In one selectable embodiment of the invention, the data receiving device receives Y + 1 signals, removes noise in the Y + 1 signals, acquires X signals and transmits them to the receiving unit. A filtering unit 407, where Y + 1 ≧ X.
In this embodiment, the time parameter unit 401 is determined and the current data transmission time parameter is determined.
In the optional implementation method of the present embodiment, the time parameter of the current data transmission time is determined after the confirmation in the time parameter unit 401 is confirmed or the confirmation is obtained from the time parameter unit 401 data transmission device. After obtaining from the confirmation unit 401 and other devices are confirmed, and after confirmation is calculated through the method of depositing the time parameter unit 401, it is confirmed. For example, before receiving data, the data receiving device first receives the signal handshake, the handshake and the signal determination for the time being the data transmission time parameter. The current data transmission time parameter determination method that is not limited to this application, and if it can be finalized, the data transmission time parameter method should all belong for the time being.
X 403 for the receiving unit, the time interval between the start times of the two signals adjacent to the received signal confirmation X signal, and X-1 time interval, where X is a positive integer and X> 1.
In the optional implementation method of this embodiment, the reception unit X 403 reception signal detection is X times low level pulse is detected X times high level pulse. The waveform display of high and low level pulses can be divided into square wave, positive wave, triangular wave, etc. that can adopt the same low level pulse / high level pulse, but this is not limited. The preferred low level pulse detected, ie, the data transmitting device provides data at the receiving device, and under high level circumstances, the low level pulse. In this system, an electrical component that provides power consumption of the data receiving device as a high-level power supply that provides the data receiving device that can use the data transmitting device during data communication with the data receiving device. For example, as a high-level charge for a device that provides data using a received data transmission device, a power supply installed in the data reception device, or a high-level power supply for a direct use data transmission device. The data receiving device adopting this method uses a single line of information alternately, and at the same time complete power supply and information are received, and the equipment volume and manufacturing cost are reduced.
In the optional implementation method of the present embodiment, a satisfactory design relationship is established between the handshake receiving unit 405 including the reception data device, and the K signal detection K signal for receiving the unit, and K and an integer of K. There is only a time interval that occurs only between two adjacent signals, so it receives at least two signals and has a handshake, and at least one time interval. The K signal is a handshake signal with a satisfactory design relationship between the receiver and the K signal. From the receiving handshake signal on the receiving side, the update data transmission efficiency from the position of the handshake signal judgment data transmission.
Furthermore, the time interval between the K signals that can be detected by the handshake receiving unit 405 satisfies the judgment first time interval and the second time interval, or during the design relationship, the first time interval among them is the i-th signal. The time interval between the start of i-1 and the start of the i-1 signal, the second time interval is the time interval between the start of the i th signal and the start of the i + 1 signal, i = 4 Well, ... 2j, j = (K-1) / K is K, and if K is odd, the relationship between the 1st time interval and the 2nd time interval satisfaction design, that is, the signal of the definite reception K is the handshake signal, Of the received data transmission signal, the trigger unit 403 received X signal, of which K is scheduled in advance. In addition, if the design relationship does not satisfy the one time interval and the second time interval, and then the time interval between the detected subsequent K signals, the determination follows the first and second time intervals of the subsequent K signal. The design-related K signal to detect whether or not the design-related K signal, under the circumstances up to the handshake signal in the inspection, the received data detection device can avoid the received data from the handshake signal until the handshake signal is detected, thereby the data The figure of sending a signal to the receiving device when the transmitting device malfunctions, and the start of judgment data. Furthermore, a satisfactory design relationship between the 1 hour interval and the 2nd time interval is a promised relationship between the data transmitting device and the data receiving device in advance, for example, the second time interval is twice the first time interval. The design-related received signal that determines whether the data receiving device satisfies the received data is the handshake signal. For example, when the received signal is included, the time intervals t0, t1, t2 and wine may include the first time interval t0 and t2, and the second time interval may include t1 and wine. Has a satisfying design relationship at the first and second time intervals: t1 = 2t0 wine = 2t2.
Furthermore, the K signal of the handshake receiving unit 405 is also a portable time parameter. Therefore, in this optional implementation method, the time parameter unit 401 of the received data device is determined, and the determined time is determined by the K signal parameter. Optionally, the time is fixed, the parameter unit 401 is determined, the first time interval set and the second time interval set, at least the first time interval including the first time interval, and at least the second time interval set One second time interval, based on which the first and second time interval set time parameters. For example, if the handshake signal sent by the data transmission device, the first time interval t 1 = etu, the second time interval t 2 = etu + pdt, the data reception device is set to the first time interval and the second time interval time parameters. Etu and pdt can be confirmed. In the case where the fixed time, overcoming data receiving device theory and actual time parameter are not consistent with the K signal parameter, the accuracy of data transmission is guaranteed.
And similar to the data transmission signal, the use of the data receiving device in the handshake receiving unit 405 detects the reception K signal under the circumstances of K times low level pulse. Alternatively, it can detect K high-level pulses and confirm that a K signal has been received. A square wave that can be realized by a method such as a positive wave by using this low / high level pulse. Priority adoption detection Low level pulse, that is, providing data receiving device from data transmitting device, when high level, necessary sending K signal generation, K times low level pulse, such as when data transmitting device and data receiving device communicate As a high-level power supply for devices that provide data transmission devices that use received data, or as a power supply installed inside the data reception device or as a high-level power source on the direct-use transmission side, the same type of equipment is used to alternately exchange information. The volume of the equipment and the manufacturing cost are reduced by receiving the completed power supply and information at the same time as using the book wire.
The above is the specific example of the method for obtaining the received K signal and the time parameter of any one of the embodiments.
In the optional implementation method of this embodiment, the filter unit including the reception data device gets the interference of the reception Y + 1 signal to the Y + 1 signal, and the X signal is Y + 1 X, the data reception device A description of any of the examples from the specific examples of the filters.
For the data acquisition unit 404, obtain the parameter corresponding to the current data transmission time of the parameter unit 401 confirmed by time, and obtain a numerical value corresponding to 1 hour interval at each continuous S time interval at X-1 time interval, and S time interval The numerical value of transmission is one of 2N different values of N-bit data, including the numerical value corresponding to 1 hour interval for data transmission of S time interval, in which S> 1 under the circumstances The time interval is the same, X and S are all positive integers, S ≦ X-1 N. In other words, in the case of X-1 time interval and S> 1, if 1 S consecutive, the N-bit data value corresponding to the 1 time interval is transmitted at the same S time interval. For example, in the time interval for receiving signals, the time intervals for consecutive signals are the same.In other words, the N-bit data values displayed at the same time intervals are used for the transmitting side. N-bit data corresponding to 1 hour interval is obtained at the time interval, and the numerical value of Shinichi Step's time interval transmission is data transmission at 1 time interval when S = 1.
As an example of this application, the parameter unit 401 confirms and confirms the current data transmission time parameter of the parameter unit 401 confirmed by time, and obtains a numerical value corresponding to 1 hour interval in each continuous S time interval, The numerical value of the time interval transmission of S can be adopted, and various numerical methods can be obtained and the numerical value corresponding to the calculated 1 hour interval. For example: m time interval = etu + m * pdt obtained time interval corresponding to the calculation method of the negotiation or decision in advance, for example, the time interval of reception is the numerical calculation of pdt obtained m according to etu. For example, if m = 1, each set of data set or negotiated in advance is 1 bit, its value is 1, if each set of data is bit, its value is 01, and if each set of data bits is If the number is 001, one data is more or less bits, the numerical method is the same.
In this example, according to the optional embodiment of the application, the fixed current data transmission time parameter is obtained as a numerical value corresponding to 1 hour interval at each continuous S time interval at X-1 time interval, and S time interval transmission The numerical value of 2N is included in the numerical value different according to the number of N bits, among them, under the condition of S> 1, the time interval of S is the same, X and S are all positive integers, S ≦ X-1 N:
Determine the current data transmission time parameter determined by the X-1 time interval, obtain a bit skewer corresponding to 1 hour interval at each S time interval, S time interval transmission bit skewer, of which S time interval In the case of a bit skew corresponding to one time interval, S> 1, the time interval of S is the same, S is a positive integer, and S X−1 ≦. For example, X =, S = 1 o'clock, I am a time interval, and the same time interval is a bit skewer; X is more than or equal to, S = 1 is acquired at many time intervals, each time interval Corresponding bit skewer: X = san, S = When two time intervals, the two time intervals are the same, and the time interval corresponding bit skewer, these two time intervals are the same time interval corresponding bit skewer ; If X is greater than or equal to, S = is set to 4 time intervals, one time interval bit skew in the previous 2 consecutive time intervals, and the next 2 consecutive time intervals One time interval corresponds to another bit skewer, ie up to 2 hour interval is bit skewer, after 2 hour interval is another bit skewer. Of course, with the above example, all of the bit skewer methods of sampled, time-sequential transmission of S as much as possible should belong to the protection scope of this application.
In the optional implementation method of this embodiment, the possible time interval including the reception data device is the acquisition unit 402, the data acquisition unit 404 acquisition X-1 time interval, and the time before the numerical value of the first continuous S time interval transmission. In addition, the correspondence of time intervals different from 2N values including parameters of N bit data, while in contrast to the time intervals corresponding to different numerical values, N is 1, 2N values of pre-calculated N bit data including the above According to the data of the number of reception time intervals, which is different from the time interval, the decoding time after the reception data is further reduced. In this example, depending on the optional embodiment of the application, the time is included in 2N different numerical values and the time interval including the N bit data parameter. Depending on the length of the parameter, 2N corresponds to the relationship between each bit bit skewer and the time interval in N. Among them, 2N bit skewer is different, and different from the time interval corresponding to different bit skewers, N is one.
In the optional implementation method of this embodiment, 2N different numerical values including N bit data can be understood: for example, N = one hour, including one bit data, the 21 different numerical values are 0 and 1 respectively; N =, sometimes including bit data, the 22 types of numbers are 00.01, 11, and 11. 2 N different values of parameters including time in N-bit data and the correspondence between time intervals: For example, I N = Time is a time interval parameter corresponding to 0, Time is a corresponding time interval parameter; Is the time interval corresponding to the parameter, the time corresponding to the parameter interval corresponding to 00, the time corresponding to the time interval parameter corresponding to 01, the time corresponding to the parameter corresponding to the time interval, and the time corresponding to the parameter every time. Of course, when N takes other values, it is the same as the above understanding method, and will not be described here anymore.
It is possible to adopt the option, N = n, such as the calculation method of data receiving device and data transmission device and the calculation method of negotiating decision and the time interval of numerical value calculation of data, m time interval for transmission data The calculation method of: time interval corresponding to the numerical value m = etu + m * pdt (in which 0 m 2n-1 ≦≦ first time, etu parameter, pdt second time parameter, eg etu = 10 μs, pdt = 30 μs), that is, the calculation method at the time interval corresponding to the numerical value 10 μs + 3 * 30 μs = Hyaku μs, leave the time according to the data calculated by the option implementation method. Of course, this application can be adopted, and the calculation method fixed time interval of the discussion in advance, this implementation is not specifically limited. Extensibility of guaranteed data transmission, ie, how much N is the time interval between the calculation method and data numerical calculation through prior consultation, that is, the time interval of numerical calculation corresponding to the data transmission device and data reception device. Later, by receiving the time interval and time interval calculated by the data transmission device, the numerical value corresponding to this time interval is directly determined, and the data efficiency.
Another option implementation method as an example of this application. Adopting data receiving device and data transmitting device Predetermining the memory list in advance adopts the time interval corresponding to the numerical value of the data, the search list is fixed and obtains the time interval of the numerical value of this data, Time interval efficiency.
In the optional implementation method of this embodiment, X-1 = n * S, where n is an integer and n is an integer, and this optional implementation method, X signal transmission n * S, and the data of the same thing is an extra signal No decryption problem.
In the optional implementation method of this embodiment, a rule is stored in the update time parameter unit 406 and the replacement time parameter for the same unit including the reception data device, and a new time parameter to be used instead of the current use time parameter is used for the time being. Data transmission time parameter, up to the received X signal, the time interval between the start time of the two signals adjacent to the definite X signal, get X-1 time interval, and the current data transmission usage time X-1 parameter time interval In each continuous S time interval, a numerical value corresponding to one hour interval is obtained, and in the S time interval transmission numerical value, the data transmission corresponding to the S time interval includes a numerical value including N-bit data. It is one of 2N different numerical values. Among them, in the case of S1, the time interval of S is the same. In this implementation plan, the data transmission device and the data reception device are completed through the determination of the new time parameter. Parameter of time when data should be used for table type data. The time parameter of the data transmission device can be changed precisely, the data processing capacity of the data receiving device, or a different type of data, improve the data processing efficiency. Specifically, refer to any of Examples 5 to 9.
In the option implementation method of this embodiment, the receiving unit 403 completes the last received data, the receiving unit A is 403 received signal (Y + 1 is an integer), the same handshake signal as the final signal is The format signal receives data to determine if the end-of-life signal data receiving device is also over.
In the optional implementation method of the present embodiment, after the reception unit 403 completion reception last data or after receiving the reception unit 403 completion reception last data, A receives the signal before the reception unit 403 through the inspection data that can be received, According to the inspection number data, the data receiving device also judges whether the received data is completely correct. The inspection data is the inspection data calculated by the parity method such as MAC inspection, parity, taking and checking.

第二装置新た時間パラメータ後、テーブルに含まれるかどうかを探す新時間パラメータでeduとpdtのこと。もし検索、説明は第二装置に新しい支持時間パラメータをデータ伝送、例えば、新しい時間をedu＝ごじゅうパラメータus、pdt＝ごus際、上記の表で検索できる時間をいちパラメータ標識の時間パラメータと新時間同じ説明パラメータは第二装置によってedu＝50us、pdt＝5usデータ伝送。さもなくば、第2装置は新しい時間パラメータによってデータ転送を行うことを支持しないことを説明する。
もちろん、オプションのとき、週波数情報を新採用時間パラメータ標識時も、第二装置支持のデータ伝送時間パラメータ表に存在するかどうかを新しい検索時間パラメータ標識、もし新しい検索時間パラメータ標識、確定第二装置によって参数時間サポート新しいデータ伝送。

実施例9
本申請実施例も提供して1種数によると伝送システム用に、上記のデータ伝送執行方法、このシステムの機能を実現して上記の実施例からはちご参照に関する記述、同じまたは類似の流れでもう贅言。本システムの第1装置と第2装置は、主にデバイスから。主とする設備の装置例えば端末としては、例えば設備からの装置は電子決済設備（例えば、電子署名ツールキー、スマートカード、キーカード合一設備など）。
以下はこのシステムについて簡単に説明する：
図じゅうさん通り、そのシステムを含む：第一装置と第二装置、その中に、第装置、情報を得るために、週波数、そして第二に送信装置の週波数情報;第二装置、受信装置の週波数に初めて送信情報によると週波数情報確定データ伝負け新時間パラメータ;支持新しい時間通りにパラメータをデータ伝送の時は、新時間パラメータ新た時間パラメータで2Nの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係によると述べた対応関係に送信データ信号、あるいは、時間通りによって新しいデータ受信信号パラメータをデータによって信号の中の時間間隔を獲得のごとく時間間隔対応ビット串、そのうち、2Nのごとくビット串別個、しかも違うようにビット串対応の時間間隔と違って、Nですいち。
サンプル性の、最初の装置が握手と信号伝送週波数情報、週波数情報は新しい時間パラメータ;この時、第一装置、具体的に時間に新しいパラメータ確定第一時間間隔組と/あるいは第二時間間隔に応じて組;第1時間間隔組と/あるいは第二時間間隔組発生Kの握手信号新しい時間を含む、握手信号パラメータ、一時間間隔を含む少なくとも1つのグループの第1時間間隔で、第2時間間隔組を含む少なくとも1つの第二時間間隔で、最初の時間間隔と第二時間間隔の間にいっぱい足デザイン関係、第1時間の間隔をｉ番目の握手信号の始まりと第i-1つ握手の信号の開始時刻の間の時間間隔で、第二時間の間隔をｉ番目の握手信号の始まりと第i+1の握手信号の開始時刻の間の時ｉ、i＝2、4、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
第二装置、具体を得るために、Kの握手信号の中の第一時間間隔組と/あるいは第二時間間隔組；第一時間間隔組と/あるいは第二時間間隔組確定データ伝送の新しい時間パラメータ。
サンプル性の、最初の装置をデータ信号伝送週波数情報、週波数情報は新しい時間パラメータ;この時、第一装置によって具体的にデータ伝送の現在の時刻を当面パラメータで2Nパラメータ時間の長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係によると対応関係が発生するFデータ信号、そのうち、すべてのデータ信号の始まりと隣接するのにひとつの信号の開始時の時間間隔をビット串対応の時間間隔で、FですいちかつFを自然数、Fのデータ伝送時間手紙号新しいパラメータ;第2装置、具体的に時間に応じてパラメータデータ信号を受信FにFデータ信号に各データ信号の開始時の間の時間間隔新た時間パラメータ。
サンプル性の、最初の装置をデータ信号伝送週波数情報、週波数情報は新しい時間パラメータ標識；この第装置、具体的にデータによって伝送の現在の時刻を当面パラメータで2Nパラメータ時間の長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係によると対応関係が発生するFデータ信号、そのうち、すべてのデータ信号の始まりと隣接するのにひとつの信号の開始時の時間間隔をビット串対応の時間間隔で、FですいちかつFを自然数、Fの新しいデータ信号伝送時間パラメータ標識；第二装置、具体的に時間に応じてパラメータデータ信号を受信FにFのデータ信号の中の時間間隔新た時間パラメータ標識、デフォルトの検索時間表に新しいパラメータ標識対応の新時間パラメータ。
また、初めて装置を行うことができるかどうかをお知らせするための週波数、第二装置での使用によって、支持新時間パラメータをデータ伝送には、その時現在で2Nパラメータの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係に初めて装置を示すために発送確認情報のデータ信号の週波数。
サンプル性、本実施例のシステムを提供する申請中の第二装置も実現することができるかどうか判断に自身の支持新時間パラメータをデータ伝送の機能は、具体的にする：
第二装置、新たに時間かどうか判断パラメータ自身で支持のデータ伝送時間パラメータの範囲内で、もし判断する新時間パラメータが自身のデータ伝送時間サポートパラメータの範囲内で、第二装置によって確定支持新時間パラメータをデータ伝送か；、
第二装置、支持されている自身のデータ伝送時間パラメータ表に検索が存在するかどうかを探すなら新しい時間パラメータは、新しい時間パラメータ、確定第二装置支持に新しい時間パラメータをデータ伝送。
本実施例の提供するシステムの中に中断データ伝送の情況の下で、初めて装置をデータ信号に第二装置の週波数情報送信、第二装置による情報データ伝送の週波数を使用して新しい時間パラメータ新時間パラメータをデータの吸収と/または送付して、データの伝送時通信パラメータの調整、効率を高めた通信。

実施例10
本実施例1種の方法を提供した受信、使える方法は信号の受信側（例えば、上記各実施例での受信側やデータ受信装置）、受信信号を濾過して、有効信号。
図じゅうよんは本実施例の提供する受信方法のフロー図のように、じゅうよんに示すように、この方法は主に以下のステップ（ステップS1402 -ステップS1410）。
ステップS1402を2Nの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係で、その中、2Nのビット串別個、しかも違うビット串対応の時間間隔と違って、Nですいち。
本実施例の中で、長さはNのビット串に対応できるの時間間隔で、多くの時間間隔でも対応できさえすれば、違うビット串対応の時間間隔で同じでない。
本実施例のオプション実施方式では、現下のデータ伝送時間のパラメータを2N長さをNの中でそれぞれのビットビット串串と時間の間隔の対応関係。中には、現在のデータ伝送の時間のパラメータはあらかじめ送信側と協議し、又は、送信側から送ったデータによって、例えば、送信側が送信データの前に、先に発送握手信号、握手と信号を受信側に伝送当面データ伝送時間パラメータ、具体的な本しない限定実施例。したがって、本実施例のオプション実施方式では、上記の対応関係を前に、確定可能時間パラメータ。はN＝にを例にして、もし二つある時間eduとpdtパラメータは、長さにの各ビット串対応の時間間隔がいち表の通り。もちろん、これに限らない、実際には、それぞれのビット串対応の時間間隔時間とパラメータの対応関係を採用することができる、表いち述べたその他の関係を具体的にもう贅言。

もちろん、これに限らない、本実施例の別のオプション実施方式では、こともできない時間によってパラメータを上記の対応関係ではなく、あらかじめ設定したルール（例えば、上記の表いち）、直接上記の対応関係を得て、例えば、N＝いちの場合、直接約束ビット0とビットいち対応の時間間隔で、例えば、それぞれじゅうμsとじゅうごμs。または、上記の対応関係を受信しておくこともでき、具体的に本実施例は限定しない。
は時間によってパラメータを上記の対応関係の場合は、データの受信側採用とデータの送信側事前協議決定するの計算方法とデータビット計算の時間間隔のときのようなN＝n、送信データビットmの時間間隔TM＝etu+m * pdt（0 m≦≦2n-1）も他の事前協議を採用することができるの計算方法確定時間間隔で、本実施例の具体的な制限はしない。事前協議を通じての計算方法を算出するこのデータビットの時間間隔で、保証データの伝送の拡張性、すなわちどんなにNのことはいくらで、送信側と受信側も計算データビットの時間間隔。
ステップS1404、受け取りY+1信号、中に、同Y+1信号の中の第一個の信号を指示用データ伝送開始の合図がいち、Yです、しかもYは正整数で、Y+1を受信信号の総数。
本実施例の中に指示、データ伝送開始の合図はデータの伝送の第一個のデータ信号、例えば、予定の時刻（同時刻、受信側と送信側約束確定）の受信後、初めてのデータ信号を送ったら、あるいは、受信側端に発データ前に、受信側に送って握手信号は、データの伝送開始の合図に指示も受信送信側からの握手信号の中の最後の信号。本実施例、握手信号は、送信側に指示データ送信受信側の開始時の信号は、また、本実施例の中で、送信側も握手と信号伝送上記時間パラメータ。
例えば、送信側のご送信の握手信号パラメータ、時間を含む2：etuとpdt握手し、ご信号の時間間隔でそれぞれ：t0、t 1 t 2とは、ワインをt0＝etu、t 1＝etu+pdtは、受信側によると確定することができt0 t 1時間etuとパラメータpdtのこと、あるいは、によっても第二時間間隔組中のt 2とワインは確定して、2t2＝2etu、2t1＝に（etu+pdt）、受信側によるとワインも確定できt 2時間etuとのことpdtパラメータ。あるいは、t0とt 1も満足できるその他の関係を通じて、限りt0とt 1のことを得ることができる時間etuとのことでpdtパラメータ。また、もし時間パラメータが一つだけは直接できKの握手信号の中の一つの時間間隔で決定するこの時間パラメータ、あるいは、もし時間が3つのパラメータは、Kの握手を通じて信号の間の時間間隔で満足の関係によって確定３時間パラメータのこと具体的な実施例、もう贅言。Kの信号を通じて握手するパラメータを克服する時間、受信側の理論と実際の時間パラメータ時間パラメータが一緻しない場合には、データの伝送の正確性を保障する。
ステップS1406に指示、データ伝送開始の合図が確定は第一個の有効信号。
S1408判断手順、受信第Z信号のスタート時には、前の有効信号のスタート時の時間間隔を得るかどうかの通りの対応関係の中の一つの時間間隔で、もしは、第Z信号を有効に信号を記録、そのうち、Z＝に、さん、よんしよ、……、Y+1。
は、ステップS1408で順次判断を受信第Z（Z＝に、さん、よんしよ、……Y+1）、信号の開始時には、前の有効信号のスタート時の時間間隔を得るかどうかの上記の対応関係に記録の時間間隔で、第Y+1信号まで判断が終わるまでは、該当する要求信号記録を有効に信号を捨てられないし、該当する要求信号効率よくろ過落ちチャネルの雑音信号、保証データの伝送の正確性と完全性。
たとえば今伝送時間のパラメータを2時間のパラメータ、つまり第一時間パラメータetuと第二時間パラメータpdt、そのetu＝じゅうμs、pdt＝にじゅうμs。Ｎ＝いち時に時間の長さをいちのパラメータをビット串（つまりいちビットのデータやいち位ビット串）に対応した時間間隔、すなわち0対応の時間間隔をetu、いち対応の時間間隔をpdt。受け手確定初めて有効信号を受信後、順次に殘りのY信号を判断して、受信に第に信号を同信号の開始時に計算すると最初の有効信号免許の始まり時の時間間隔をじゅうごμs、同時間間隔といち位ビット串0といち所対応の時間間隔は同じないため、信号は有効信号は、同信号記録を無効にする信号Dは、当該無効信号Dを捨てて。
判断の信号のスタート時第さんと初めて有効信号C 1のスタート時の時間間隔をにじゅうμs、同時間間隔といち位ビット串いちに対応した同じ時間間隔ため、信号は有効信号は、同信号記録を第2の有効信号C 2し、同第二の有効信号C 2の開始時に。
第よんしよ判断の信号の開始時刻と第2の有効信号C 2のスタート時の時間間隔……このため、受信に至るまで、判断の第Y+1信号が終わるまで。
本申請実施例のオプション実施案で、第Zの信号のスタート時には、前の信号のスタート時の時間間隔はデフォルト値より大きい。すなわちこのオプション実施案では、ステップS1404中、初めて有効信号完成受信後、受信側のハードウエア層ろ過落ち当面信号の始まり時刻と前の信号のスタート時の時間間隔がデフォルト値の当面の信号は、受信側のMCUいやな信号に応答しても、現在の信号の開始時にだけ、前の信号のスタート時の時間間隔はイコールデフォルト値の現在の信号（すなわち第Z信号）を高めることができて応え、後続の有効信号検出効率を減らして、少なくMCUの作業負荷。
さらに、上述のハードウエア層のフィルタを採用することができる以下方式：受信側からの信号を受信機に受信の第一個の有効信号のスタート時Tからクロノグラフ、T +デフォルト値の範囲内のいかなる信号を受信しない時間で、自T +デフォルト値この瞬間から重い新から受信信号受信信号まで第Z（Z＝に）を、同第Z信号（Z＝に）の開始時刻と新たなT、上記の手順を繰り返してまで、第Y+1受信信号まで。
さらに、上述のデフォルト値をステップS1402取得のごとく対応関係の中の時間間隔の最小値。現在の信号の開始時から、前の信号のスタート時の時間間隔が同対応関係の中の時間間隔の最小値、きっと当面信号は有効信号を受信しないので、この現在信号。
本実施例のオプション実施方式では、受信Y+1信号は検出されY+1度ローレベルパルスは、検出されY+1度高いレベルパルス。同ローレベルパルス/高レベルのパルスを採用することができる方形波、正絃波、三角波などに分けて高低レベルパルスの波形表示、ここは限定しません。ステップS1410に判定結果を得て、X有効信号、中に、X≦Y+1、しかもXは正整数。
ステップS1408の判断によって、Xの効果的な信号によるX有効信号で復号化し、送信側のデータを送信。したがって、本実施例の申請のオプション実施案では、手順S1410た後でも、以下の手順を含むS1412 -ステップS1416（図に未を示す）。
ステップS1412、確定中X有効信号ごとに2つの信号の始まりに隣接する時の間の時間間隔で、得X-1時間間隔。
ステップS1414に取得の対応関係をX-1時間間隔で各連続Sの時間間隔で1時間間隔対応ビットの串を得て、Sの時間間隔伝送のビット串、そのうち、Sの時間間隔で伝送するビットの串を1時間間隔対応ビット串、S＞のいち場合、このSの時間間隔が同じで、Sは正整数で、S X-1≦。
本実施例のオプション実施方式では、X-1＝n * S、nですいちかつnを整数を採用し、このオプション実施方式、X信号伝送n * Sまた同じことができるデータビットではないが、余分な信号による復号化問題ない。
例えば、私X＝に、S＝いち時、俺は時間間隔で、同時間間隔を対応ビット串；Xをさんや以上、S＝いちにしたのは、多くの時間間隔で取得し、各時間間隔対応ビット串；X＝さん、S＝に時は、2つの時間間隔で、この二つの時間間隔が同じであり、かつ、その時間間隔対応ビット串、この二つの時間間隔は同一時間間隔対応ビット串；Xをごとき、S＝ににしたのは、4つの時間間隔で、前の2つの連続した時間間隔の中の一つの時間間隔対応よりッター串、後の2つの連続した時間間隔の中の一つの時間間隔対応別のビット串、すなわちまで2時間間隔はビット串、後2時間の間隔は別のビット串。もちろん、以上の例を挙げてただサンプル性の、できる限り得Sの時間間隔伝送のビット串の方式は全て属するべき本申請の保護範囲。
ステップS1416、X-1時間間隔で各連続Sの時間間隔伝送のビット串を切り替えを得て、このX-1時間間隔のビットシリアル伝送。
例えば、仮にＸ＝きゅう、く、S＝いち、ステップS1414で得はちの時間間隔で、それぞれの時間間隔対応ビット串順に「01」、「00」、「01」、「じゅう」、「じゅういち」、「じゅう」、「00」と「01」は、最後に入手このご時間間隔伝送のビットシリアルを「0100011011100001」。
任意に、得たX-1時間間隔伝送のビットシリアルで復号化し、得X-1時間間隔伝送のデータは、復号化した時に、はち位でビット組組成のバイトし、その結果X-1時間間隔のデータ伝送。
本申請実施例のオプション実施案では、X-1時間間隔伝送のビットシリアルも含む検査ビット、例えば、最後のバイトを検査位と、さらなる同検査位に検査ビット前のデータの完全性検査。データの完全性検査を含むがこれに限らない、CRC奇偶検査、デジタル署名、取りや検査、MAC検査など。
任意に、上記Y+1信号の後、受け手が送受信端からのAが信号（Aですいちしかも整数）、あるいは、Aが信号も含めY+1内の信号。終瞭信号と同じ握手信号は、他の特定のフォーマットの信号を通じて、終瞭の信号は、受信側がデータビット串受信終わりかどうか判断。
本実施例の提供するを通じて受信方法、有効なろ過落ち騒音、受信の効率を高める。

実施例11
本実施例を提供する1種の受信方法、図じゅうごは本実施例の提供する受信方法のフローチャート。本実施例の提供する方法と実施例1提供方法の違いは、実施例じゅう中受け手は受け取るY+1信号から順次各信号を有効かどうか判断信号、本実施例の中で、最初の有効信号確定後、すべて受信信号は即座に判断この信号は有効かどうか信号。実施例10に比べて、本実施例で提供される方法の効率はさらに高い。
図じゅうご通り、本実施例の提供する同受信方法は主に以下の手順（ステップS1502 -ステップS1508）。
ステップS1502を2Nの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係で、その中、2Nのごとくビット串別個、しかも違うようにビット串対応の時間間隔と違って、Nですいち。
本実施例の中で、長さはNのビット串に対応できるの時間間隔で、多くの時間間隔でも対応できさえすれば、違うビット串対応の時間間隔で同じでない。
本実施例のオプション実施方式では、現下のデータ伝送時間のパラメータを2N長さをNの中でそれぞれのビットビット串串と時間の間隔の対応関係。中には、現在のデータ伝送の時間のパラメータはあらかじめ送信側と協議し、又は、送信側から送ったデータによって、例えば、送信側が送信データの前に、先に発送握手信号、握手と信号を受信側に伝送当面データ伝送時間パラメータ、具体的な本しない限定実施例。したがって、本実施例のオプション実施方式では、上記の対応関係を前に、確定可能時間パラメータ。
もちろん、これに限らない、本実施例の別のオプション実施方式では、こともできない時間によってパラメータを上記の対応関係ではなく、あらかじめ設定したルールを得て、直接上記の対応関係について、例えば、N＝いちの場合、直接約束よりッター0とビット対応のいち時間間隔で、例えば、それぞれじゅうμsとじゅうごμs。または、上記の対応関係を受信しておくこともでき、具体的に本実施例は限定しない。
は時間によってパラメータを上記の対応関係の場合は、データの受信側採用とデータの送信側事前協議決定するの計算方法とデータビット計算の時間間隔のときのようなN＝n、送信データビットmの時間間隔TM＝etu+m * pdt（0 m≦≦2n-1）も他の事前協議を採用することができるの計算方法確定時間間隔で、本実施例の具体的な制限はしない。事前協議を通じての計算方法を算出するこのデータビットの時間間隔で、保証データの伝送の拡張性、すなわちどんなにNのことはいくらで、送信側と受信側も計算データビットの時間間隔。
ステップS1504、受信に指示データ伝送開始の合図として、この信号は第一個の有効信号。
本実施例に指示データ伝送開始の合図はデータの伝送の第一個のデータ信号、例えば、予定の時刻（同時刻、受信側と送信側約束確定）の受信後、初めてのデータ信号、またはそれを送信側にデータを受信側から前に受信側に送って握手信号は、データの伝送開始の合図に指示も受信送信側からの握手信号の中の最後の信号。本実施例、握手信号は、送信側に指示データ送信受信側の開始時の信号は、また、本実施例の中で、送信側も握手と信号伝送上記時間パラメータ。
ステップS1506、引き続き受信、判断を受信する第Z信号のスタート時には、前の有効信号のスタート時の時間間隔を得るかどうかの通りの対応関係の中の一つの時間間隔で、もしは、第Z信号を有効に信号を記録、そのうち、Z＝いち、に、さん、よんしよ、……Y、Y、Yは受信し続ける信号の数で、Yは正の整数である、
順次判断を通じて受信第Z信号のスタート時には、前の有効信号のスタート時の時間間隔で、上記の対応関係かどうかに記録の時間間隔で、第Y信号まで判断が終わるまでは、該当する要求の信号を記録して捨てない信号が効果、該当する要求の信号が有効ろ過落ちチャネルの雑音信号、保証データの伝送の正確性と完全性。
例えば、当面の伝送時間パラメータを第1時間パラメータetuと第二時間パラメータpdt、そのetu＝じゅうμs、pdt＝ごμsを例にして、N＝に時、ステップS1502中に時間を長さの違うパラメータにデータビット対応の時間間隔で、表に示す。

受信データ伝送用で指示開始の合図の第一個の有効信号免許の後、仮にじゅうμs後受信第いち信号その信号の開始時刻と初めて有効信号のスタート時の時間間隔をじゅうμs、同時間間隔と表2：00により串対応の時間間隔で同じため、信号を有効に信号を記録、信号を第2の有効信号C 2し、その第2の有効信号C 2の開始時に。
第に受け続け、信号は、計算を同信号の始まり時刻と第2の有効信号C 2の始まり時の時間間隔をじゅうろくμs、同時間間隔と表2ビット串00、01、じゅうとじゅういちに対応した時間間隔は同じではないため、信号を有効に信号をこの信号記録を無効にする信号Dは、当該無効信号Dを捨てて。
受信第Z信号（Z＝さん）に、その信号を計算する必要の開始時刻と第2の有効信号C 2のスタート時の時間まで、このため、判断を受信第Y信号が終わるまで。最後に入手ろく有効信号（C 1〜C6）。
本実施例のオプション実施方式では、受信初めて有効信号と受け続けてのY信号は検出されY+1度ローレベルパルスは、検出されY+1度高いレベルパルス。同ローレベルパルス/高レベルのパルスを採用することができる方形波、正絃波、三角波などに分けて高低レベルパルスの波形表示、ここは限定しません。好ましいを検出した低レベルパルス、すなわち送信側で受信側を提供し、高レベルの情況の下で、低レベルパルス、この方式では、受信側送信側と通信の時、受信側を使用できるように送信側提供の高レベルの電源として、受信側の消費電力を提供する電気部品例えば、受信側が利用できる送信側提供の高レベルの充電方法の設備を採用し、情報を交互に一本の線を使うと同時に完成給電と情報を受信し、小さくなった設備の体積や製造コスト。
ステップS1508、受け取るY信号による判定結果を得た後、、X有効信号、中に、X≦Y+1、しかもXは正整数。
受信完Y信号を経て、ステップS1506の処理、X有効信号、フォローアップの復号化の過程の中で、当該X有効信号で復号化し、その結果を送信側のデータ送信。
本実施例の提供するを通じて上述の方法に指示、受信データ伝送開始の合図の後、その信号記録を有効に信号を受信ごとに、後続の信号は、この信号が前の有効信号の間の間隔を判断して、もしその時の間との間隔は長さをN任意のビット串対応の時間間隔は、この信号無視すれば、時間の間隔はと長さをNのその中の１つのビット串対応の時間間隔は、この信号記録を有効に信号を通じて、この方法を効果的に手紙とノイズ干渉信号を高め、データの伝送の正確性と安定性。
本申請実施例のオプション実施案では、手順S1508後は、さらに効果的にX信号で復号化し、X有効信号伝送のビットシリアル。したがって、ステップS1508後、同方法を含む可能ステップS1510からステップS1514（図に未を示す）。
ステップS1510、確定のX有効信号に隣接する2つの信号ごとの始まりの時の間の時間間隔で、得X-1時間間隔。
ステップS1512に取得の対応関係をX-1時間間隔で各連続Sの時間間隔で1時間間隔対応ビットの串を得て、このSの時間間隔伝送のビット串、中に、同Sの時間間隔伝送のビット串は上記1時間対応ぶりのビット串、S＞いちの情況の下で、前記Sの時間間隔が同じで、Sは正整数で、S X-1≦。
本実施例のオプション実施方式では、X-1＝n * S、nですいちかつnを整数を採用し、このオプション実施方式、X信号伝送n * Sまた同じことができるデータビットではないが、余分な信号による復号化問題ない。
ステップS1514、X-1時間間隔で各連続Sの時間間隔伝送のビット串をつなぎ合わせて、得X-1時間間隔のビットシリアル伝送。
例えば、仮にＸ＝きゅう、く、S＝いち、ステップS1510で得はちの時間間隔で、それぞれの時間間隔対応ビット串順に「01」、「00」、「01」、「じゅう」、「じゅういち」、「じゅう」、「00」と「01」は、最後に入手このご時間間隔伝送のビットシリアルを「0100011011100001」。
本申請実施例のオプション実施案では、手順S1514た後、さらに得たビットシリアルで復号化し、得X-1時間間隔伝送のビットシリアル、復号化した時に、はち位でビット組組成のバイトの時間間隔で、その結果X-1伝送データ。
さらに、X-1時間間隔伝送のビットシリアルも含む検査ビット、例えば、最後のバイトを検査位と、さらなる同検査位に検査ビット前のデータの完全性検査。データの完全性検査を含むがこれに限らない、CRC奇偶検査、デジタル署名、取りや検査、MAC検査など。
本実施例のオプション実施方式では、受信第Z信号の始まりの時は、前の信号のスタート時の時間間隔はデフォルト値より大きい。オプションでステップS1504完成受信初めて有効信号後、受信側のハードウエア層ろ過落ち当面信号の始まり時刻と前の信号のスタート時の時間間隔がデフォルト値の当面の信号は、受信側のMCUいやこの信号は何一つも鳴るだけでは、現在信号の始まり時には、前の信号のスタート時の時間間隔はイコールデフォルト値の現在の信号（すなわち第Z信号）を高めることができて応え、後続の有効信号検出効率減ってMCUの作業負荷。
さらに、上述のハードウエア層のフィルタを採用することができる以下方式：受信側からの信号を受信機に受信の第一個の有効信号のスタート時Tからクロノグラフ、T +デフォルト値の範囲内のいかなる信号を受信しない時間で、自T +デフォルト値この瞬間から重い新から受信信号受信信号まで第Z（Z＝いち）を、同第Z信号（Z＝いち）の開始時刻と新たなT、上記の手順を繰り返し、受信まで第Y信号まで。
さらに、上記の設定値は、取得した対応関係に記録された時間間隔の最小値になることができます。現在の信号の開始時から、前の信号のスタート時の時間間隔が同対応関係の中の時間間隔の最小値は、その現在の信号に属していないS1506きっとステップ中の有効信号を受信しないために、この現在信号。
本申請実施例のオプション実施案では、引き続き受信Y信号の中が含めて送信側からのAが信号（Aですいちしかも整数）、又は、続いてY信号を受信後、送受信端から送られてきたAが信号。終瞭信号と同じ握手信号は、他の特定のフォーマットの信号を通じて、終瞭の信号は、受信側がデータビット串受信終わりかどうか判断。

実施例12
本実施例を提供する1種の受信装置、装置に執行実施例じゅうで述べた受信方法、受信装置を実施例よんしよ中のデータを受信装置、すなわち本実施例の中に説明受信装置の機能としての実施例よんしよ中のデータを受信装置機能の追加。
本実施例では、受信装置は、できるだけとは限らないスマートカードと/あるいは知能キー設備と/あるいは動態パスワードの札の機能の電子決済設備。
図じゅうろくは本実施例の提供する1種の受信装置の構造の案内図図じゅうろくに示すように、この装置は主に：時間間隔をユニット120、吸収ユニット110、記録ユニット140、判断ユニット130と有効信号取得ユニット150。次に説明を行う。
時間間隔をユニットを得るために、120、2Nの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係で、その中、2Nのビット串別個、しかも違うビット串対応の時間間隔と違って、Nですいち。
本実施例のオプション実施方式では、時間の間隔を通じてユニット120以下の方式を上記の対応関係：確定当面データ伝送時間パラメータ、に沿って、前記時間パラメータを2N長さをNの中でそれぞれのビットビット串串と時間の間隔のごとく対応関係。中には、現在のデータ伝送の時間のパラメータはあらかじめ送信側と協議し、又は、送信側から送ったデータによって、例えば、送信側が送信データの前に、先に発送握手信号、握手と信号を受信側に伝送当面データ伝送時間パラメータ、具体的な本しない限定実施例。
もちろん、これに限らない、本実施例の別のオプション実施方式では、ユニット間隔を120こともできない時間によってパラメータを上記の対応関係ではなく、あらかじめ設定したルールを得て、直接上記の対応関係について、例えば、N＝いちの場合、直接約束ビット0とビットいち対応の時間間隔で、例えば、それぞれじゅうμsとじゅうごμs。または、上記の対応関係を受信しておくこともでき、具体的に本実施例は限定しない。
は時間によってパラメータを上記の対応関係の場合、時間間隔をユニット120採用とデータの送信側事前協議して計算方法計算の長さをNのビット串に対応した時間間隔のときのようなN＝n、発送長さｎのビット串に対する時間間隔Tm＝etu+m * pdt（0 m≦≦2n-1）を採用することもできるほか、あらかじめ協議の計算方法確定時間間隔で、本実施例の具体的な制限はしない。事前協議を通じての計算方法を算出するこのデータビットの時間間隔で、保証データの伝送の拡張性、すなわちどんなにNのことはいくらで、送信側と受信側も計算データビットの時間間隔。
本申請実施例のオプション実施案では、受信装置も含め更新時間パラメータユニットのための交換時間をパラメータをトリガ時間間隔ユニット更新上述の対応関係、つまり時間パラメータユニットにデフォルト規則を更新し、現在の時間をパラメータに代える新しい時間パラメータは、新しいパラメータの時間として当面データ伝送時間パラメータ、トリガ時間間隔をユニット201下新しい時間パラメータを得るの長さを再2N Nの中でそれぞれのビットビット串串と時間間隔の通りに関係する。本実施案では、新しい時間パラメータの確定することを通じてデータ送信装置やデータ受信装置完成の協議も、データ送信装置やデータ検索あらかじめメモリーの受信装置時間パラメーターリストを完瞭するなど、発送にあるタイプでデータを表確定タイプのデータを使用するべきである時間のパラメータ。データ送信装置の時間パラメータは変化が一緻することができますによって、データ処理能力のデータを受信装置、または一緻の異なるタイプのデータを、データ処理の効率を向上させ。。
受信ユニット110用に、Y+1受信信号、中に、同Y+1信号の中の第一個の信号を指示用データ伝送開始の合図で、そのうち、Y+1を受信信号の総数。
本実施例の中に指示、データ伝送開始の合図はデータの伝送の第一個のデータ信号、例えば、予定の時刻（同時刻、受信側と送信側約束確定）の受信後、初めてのデータ信号を送ったら、あるいは、受信側端に発データ前に、受信側に送って握手信号は、データの伝送開始の合図に指示も受信送信側からの握手信号の中の最後の信号。本実施例、握手信号は、送信側に指示データ送信受信側の開始時の信号は、また、本実施例の中で、送信側も握手と信号伝送上記時間パラメータ。
例えば、送信側のご送信の握手信号パラメータ、時間を含む2：etuとpdt握手し、ご信号の時間間隔でそれぞれ：t0、t 1 t 2とは、ワインをt0＝etu、t 1＝etu+pdtは、受信側によると確定することができt0 t 1時間etuとパラメータpdtのこと、あるいは、によっても第二時間間隔組中のt 2とワインは確定して、2t2＝2etu、2t1＝に（etu+pdt）、受信側によるとワインも確定できt 2時間etuとのことpdtパラメータ。あるいは、t0とt 1も満足できるその他の関係を通じて、限りt0とt 1のことを得ることができる時間etuとのことでpdtパラメータ。また、もし時間パラメータが一つだけは直接できKの握手信号の中の一つの時間間隔で決定するこの時間パラメータ、あるいは、もし時間が3つのパラメータは、Kの握手を通じて信号の間の時間間隔で満足の関係によって確定３時間パラメータのこと具体的な実施例、もう贅言。Kの信号を通じて握手するパラメータを克服する時間、受信側の理論と実際の時間パラメータ時間パラメータが一緻しない場合には、データの伝送の正確性を保障する。
記録ユニット140は、データ転送開始を指示するための信号を第一の有効信号とする。
判断ユニット130、受信に判断第Z信号のスタート時には、前の有効信号のスタート時の時間間隔を得るかどうか時間間隔ユニット120取得の対応関係の中の一つの時間間隔で、その中、Z＝に、さん、よんしよ、……Y。
記録ユニット140、有効と判断する信号にユニット第Zの信号の開始時には、前の有効信号のスタート時の時間間隔を取得するための対応関係の中の一つの時間間隔の場合は、第Z信号記録を有効に信号。
有効信号取得ユニット150され、記録によればユニットの記録を得て、X有効信号、中に、X＜Y、しかもXは正整数。
たとえば今伝送時間のパラメータを2時間のパラメータ、つまり第一時間パラメータetuと第二時間パラメータpdt、そのetu＝じゅうμs、pdt＝にじゅうμs。Ｎ＝いち時に時間の長さをいちのパラメータをビット串（つまりいちビットのデータやいち位ビット串）に対応した時間間隔、すなわち0対応の時間間隔をetu、いち対応の時間間隔をpdt。受信ユニット110確定第いちの信号を有効に信号の後、このうち、受信に第2信号、判断ユニット130の判断で、信号の開始時刻と初めて有効信号C 1のスタート時の時間間隔をじゅうごμs、同時間間隔といち位ビット串0といちに対する時間の間隔は同じないため、信号は有効信号は、同信号記録を無効にする信号Dは、当該無効信号Dを捨てて。
判断ユニットじゅうさん続けて判断第さんの信号のスタート時刻と初めて有効信号C 1のスタート時の時間間隔をにじゅうμs、同時間間隔といち位ビット串いちに対応した同じ時間間隔ため、信号は有効信号、記録ユニット140当該信号記録を第2の有効信号C 2し、その第2の有効信号C 2の開始時に。
判断ユニットじゅうさん第よんしよ信号継続判断の開始時刻と第2の有効信号C 2のスタート時の時間間隔……このため、受信に至るまで、判断の第Y+1信号が終わるまで。
本申請実施例のオプション実施案で、第Zの信号のスタート時には、前の信号のスタート時の時間間隔はデフォルト値より大きい。すなわちこのオプション実施案では、最初の有効信号を受信した後、受信装置のハードウエア層ろ過落ち当面信号の始まり時刻と前の信号のスタート時の時間間隔がデフォルト値の当面の信号は、受信側のMCUいやな信号に応答だけでも、当面の信号開始時刻と前の信号のスタート時の時間間隔はイコールデフォルト値の現在の信号（すなわち第Z信号）を高めることができて応え、後続の有効信号検出効率MCUの仕事が減ってマイナス荷。
さらに、上述のハードウエア層のフィルタを採用することができる以下方式：受信装置の信号を受信機から受信の第一個の有効信号のスタート時Tからクロノグラフ、T +デフォルト値の範囲内のいかなる信号を受信しない時間で、自T +デフォルト値この瞬間から再スタート受信信号受信信号まで第Z（Z＝に）を、同第Z信号（Z＝に）の開始時刻と新たなT、上記の手順を繰り返してまで、第Y+1受信信号まで。
さらに、上述のデフォルト値を取得ユニット間隔120取得の対応関係の中の時間間隔の最小値。現在の信号の開始時から、前の信号のスタート時の時間間隔が同対応関係の中の時間間隔の最小値、きっと当面信号は有効信号を受信しないので、この現在信号。
有効信号取得ユニットを有効に150 X信号後、受信装置によってX有効信号で復号化し、送信側のデータを送信。したがって、本実施例の申請のオプション実施案では、受信装置は含む：確定ユニットにX確定を有効に隣接する信号二つの信号のスタート時の間の時間間隔で、得X-1時間間隔で、その中、X≦Y +いち、しかもXを正整数；データ取得ユニットに取得の対応関係によって、X-1取得の時間間隔で各連続Sの時間間隔で1時間間隔対応ビットの串を得て、Sの時間間隔伝送のビット串、そのうち、このSの時間間隔で伝送するビットの串を1時間間隔対応ビットの串いち、S＞の情況の下で、このSの時間間隔が同じで、Sは正整数で、S≦X-1；切り替えユニットには、X-1時間間隔で各連続Sの時間間隔伝送のビット串を切り替え、X-1までの時間間隔で伝送するビットの串。
本実施例のオプション実施方式では、X-1＝n * S、nですいちかつnを整数を採用し、このオプション実施方式、X信号伝送n * Sまた同じことができるデータビットではないが、余分な信号による復号化問題ない。
任意に、得たX-1時間間隔伝送のビットシリアルで復号化し、得X-1時間間隔伝送のデータは、復号化した時に、はち位でビット組組成のバイトし、その結果X-1時間間隔のデータ伝送。
本申請実施例のオプション実施案では、X-1時間間隔伝送のビットシリアルも含む検査ビット、例えば、最後のバイトを検査位、当該受信装置も含む検査ユニットには、X-1時間間隔伝送のビット串で復号化し、得X-1時間の間隔のデータ伝送し、X-1時間間隔のデータ伝送データの完全性検査。データの完全性検査を含むがこれに限らない、CRC奇偶検査、デジタル署名、取りや検査、MAC検査など
本実施例の中で各ユニットの執行の具体的な操作がさらに参照実施例いちの各オプションの実施計画の具体的な説明で、もはや贅言。

実施例13
本実施例を提供する1種の受信装置、受信装置に使うことができじゅういち執行実施例の描く受信方法、また、受信装置を実施例よんしよ中のデータを受信装置、すなわち本実施例の中に説明できる受信装置の功としてよんしよで実施例データ受信装置の機能の追加。
本実施例の提供する受信装置と実施例じゅうにの描く受信装置の違いは、実施例12中受信ユニット110受け取るY+1信号から判断ユニット130順次各信号を有効かどうか判断信号、本実施例の中、確かに初めて有効かも、信号と受信ユニット220すべて受信信号230すなわち判断ユニットの判断で、信号を有効かどうか信号。実施例12に比べて、本実施例で提供される方法の効率はさらに高い。
図じゅうななじゅうしちを本実施例が提供した受信装置の構造の案内図図じゅうななじゅうしち通り、受信装置は主に：時間間隔をユニットを得るために、2N 210、長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係で、その中、2Nのビット串互違う、違う串かつビット対応の時間間隔と違って、Nですいち;受入ユニット220、受信用に指示データ伝送開始の合図として、信号を初めて有効信号、そして引き続き受信を判断するユニット230に判断し、次のユニット220を受け続けて第Zの信号のスタート時前の有効信号のスタート時の時間間隔を得るかどうか時間間隔ユニット210取得の対応関係の中の一つの時間間隔で、その中、Z＝いち、に、さん、よんしよ、……Y、Yを受け続けての信号の数、Yは正整数；記録ユニット240さで判断をユニット230判断第Zの信号のスタート時には、前の有効信号のスタート時の時間間隔時間間隔を得るユニット210の対応関係の中の一つの時間間隔の状況の下で、第Z信号記録を有効に信号；有効信号取得ユニット250され、記録によればユニット240の結果を記録、受信ユニット220受信Y信号の中のX有効信号。
本申請実施例のオプション実施案の中に指示データ伝送開始の合図をデータ伝送の第一個のデータ信号やを受信ユニット220受信の握手信号での最後の信号。
本申請実施例のオプション実施案では、時間の間隔を通じてユニット220以下の方式を2Nの長さをNの中でそれぞれのビットビット串串と時間間隔の対応関係：確定当面データ伝送時間パラメータ、に沿って、前記参数時間の長さを取得2N Nのビット串串の中でそれぞれのビットと時間間隔のごとく対応関係。
本申請実施例のオプションの実施計画では、同受信装置は含む：確定ユニットにX確定を有効に隣接する信号二つの信号のスタート時の間の時間間隔で、得X-1時間間隔で、その中、X≦Y+1、しかもXは正整数；データ取得ユニットによって、使用時間間隔をユニット220取得の対応関係をX-1時間間隔で各連続Sの時間間隔で1時間間隔対応ビットの串を得て、Sの時間間隔伝送のビット串、そのうち、このSの時間間隔で伝送するビットの串を1時間間隔に対応するビット串、S＞いちの場合、このSの時間間隔が同じで、Sは正整数で、S≦X-1；切り替えユニットには、X-1時間間隔で各連続Sの時間間隔伝送のビット串をつなぎ合わせて、得X-1時間間隔伝送のビット串。
本申請実施例のオプションの実施計画では、同受信装置も含む検査ユニットには、X-1時間間隔伝送のビット串で復号化し、得X-1時間間隔のデータ伝送し、X-1時間間隔のデータ伝送データの完全性検査。
具体的な応用の中で、本実施例の提供する受信装置の上述の各ユニットによって実施例に述べた方式実行対応の操作で、具体的にもう贅言。

実施例14
本実施例を提供したお伝送方法によると、図じゅうはち通り、本実施例1種数によると方法を提供する伝送主に以下の手順S1801からステップS1806。
ステップ：K S1801受信信号。
Kをあらかじめ設定値、Kさんは奇数でKです、例えばプリセットK＝ごとき、そんなにご累計受信信号を受信する場合は、にご信号処理し、本実施例の提供する方法を通じて、Kの信号の間の時間間隔の関係を判断することができるかどうか受信データから、つまり、もし満足デザイン関係はKの信号の後から受信データは、このKの信号として指示から受信データの握手信号；その中、信号を受信パルス信号、つまり高レベルパルス信号（上昇に沿って手紙号）、あるいは低レベルパルス信号（下がりに沿って信号）、パルス信号は方形波、正絃波、三角波や他の不規則波形は、上記の組み合わせによって波形。
本実施例では、K個の信号を受信し、以下のように少なくとも1つを含む：
方式1：K次低レベルパルスまで検出、
この方式では、検出できる端末が連続高レベルでのK回低レベルパルスは、例えば、高レベル検出後しばらく検出いち度ローレベルパルス、そしてまた高レベルの状態まで回復検査を経て、しばらくの時間以降に、またいち度低い電検出平パルスは、このような方式でKまで回連続測定低レベルパルス、
方式2：K次高レベルパルスまで検出された、
この方式では、検出できる端末が連続低レベルのK回高レベルパルスは、例えば、低レベルの検出後しばらく検出いち度高いレベルパルス、そして再び回復低レベル検出の状態を経て、しばらくの時間以降に、またいち度高い電検出平パルスは、このような方式で連続測定Kまで度高いレベルパルス、
上記の方式で、Kの信号は跳ね上がる信号、しかも跳ね上がる幅は明らかに、便利と雑音信号を分けて。
ステップS1802：検出Kの信号に隣接するごとに2つの間の時間間隔。
本実施例で、その連続受信信号検出ＫＫ後、合図に隣接する2つの信号の間の時間間隔で、オプションにが、Ｋの信号を連続高レベルでのKの低レベルの信号の時、低レベルの信号確定第pの開始時から第p+1つ電気信号の開始時に低平の間の時間は第pと第p+1信号の間の時間間隔で、同様にが、Ｋの信号を連続低レベルの高レベルの信号にK、確定第p高レベルの信号の開始時から第p+1高レベルの信号の始まり時の間の時間は第pと第p+1信号の間の時間間隔で、その、いち≦p≦K - 1、しかもp自然数として1種のオプションの実施を通して、方法すべてのパルス信号検出の開始時、それによって正確に隣接する2つの信号を開始時刻の時間間隔。
ステップS1803：判断第一時間間隔と第二時間間隔との間には満足デザイン関係。
本実施例として1種のオプションの実施方法は、ステップS1803で1時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔はｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔で、その中、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです；サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、マークをt 2、第二時間間隔が第4号と手紙第ご信号開始時刻の間の時間間隔で、表記はワイン。判断の第1時間間隔と第二時間間隔との間にはいわゆる満足デザイン関係、と判断t0 t 1の間や、t 2とワインとの間には共に満足デザイン関係によって、このデザイン関係の技術者の経験を確定して、あるいは実際に実行時のパラメータかも確かに限り、保証が満たされるというデザイン関係確かにこのKの信号を指示から受信データの握手信号。つのオプションの実施方法として、デザイン関係をt 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2 ;や、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、その中で、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種類、ここはもう贅言。
ステップS1804：確定第一時間間隔組と/あるいは第二時間間隔組。
その中に、第時間間隔を含む第一組j時間間隔で、第二時間間隔組を含むj二時間間隔、j＝（K - 1）/に、Kさんは奇数でKです。iを取ることによってないときとともに、Kの信号発生のK - 1時間の間隔を生むシリーズの第一時間間隔と第二時間間隔で、複数の異なるの最初の時間間隔で選択少なくともいちになって第一時間間隔組が、同様に、複数の異なるからの第二時間間隔選んで少なくともいちの第二時間間隔組、例えば、K＝ごとき、ご信号発生間隔で第1時間t0、t 2、および第二時間間隔t 1、ワインは、この時、t0を取り、t 2として第一時間間隔組を取って、t 1、ワインは第二時間ぶりに組本実施例のは限界第一時間間隔組や第二時間間隔組中時間間隔の数は少なくともひとつのことを通じて、このような方式を決定することができます第一時間間隔組と/あるいは第二時間間隔組、ように時間間隔分類処理を行う。
ステップS1805：もし一時間間隔と第二時間間隔満足デザイン関係によって、前記第一時間間隔はグループ中の少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間参数。
ステップS1805によって前記第一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔で、具体的には、第一時間間隔組中の少なくとも2つの最初の時間間隔で確定当面データ伝負けた時間のパラメータによって第二時間間隔のグループに少なくとも二つの第二時間間隔確定当面データ伝送時間パラメータも第一時間間隔のグループに少なくとも一時間間隔と第二時間間隔のグループに少なくとも1つの第二時間間隔共同確定当面データ伝送時間パラメータ、かつ第一時間間隔と第二時間間隔は隣接する。
本実施例では、確定した第一時間間隔組や第二時間間隔組で、そのｉ番目の信号と第i-1信号の間の最初の時間間隔とｉ番目の信号と第i+1信号の間の第二時間間隔は満足デザイン関係の時、Kの信号を判定有効な握手信号は、この時、第一時間間隔組によって、または第二時間間隔組、または第一時間間隔組や第二時間間隔組とデータの送信側にあらかじめ約束の時間にパラメータ生成ルール、確定当面データ伝送の時の間にパラメータ、中に、あらかじめ約束の時間にパラメータ生成ルールは保証各データビット符号化方式の唯一の前提の下で、任意の種類の方式を選ぶことができる時間をパラメータの確定、
例えば、私K＝ごとき、ごの信号に隣接する2つの間の発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三つの信号開始時刻の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔ワインは、マークは、これを例によって、以下のように一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間パラメータのやり方の詳細。
本実施例の一つとしてのオプションの実施方式、選択しt0とt 2第1時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0とt 2唯一表の通りに、etuとpdtの値t0 t 2の値によると、任意計算方を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=（t0-t2）/5；
etu=t0+t2，pdt=（t0+t2）/10；
etu=t0+t2/2，pdt=(t0-t2)/5；
etu=t2，pdt=（t0-t2）/15；
……..
本実施例として別の1種の方式として選択t0オプションを実施し、第一時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0唯一は、etuとpdtの値によるとt0の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t0/5；
etu=2*t0，pdt=t0/10；
etu=t0/2，pdt=t0/5；
etu=t0/3，pdt=t0/15；
……..
本実施例として別の1種の方式を選ぶのオプションの実施、t 1とワインは第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1とワインは唯一は、etuとpdtの値によるとワインの値を通じてt 1任意計算方を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=（t1-t3）/5；
etu=t1+t3，pdt=（t1+t3）/10；
etu=t1+t3/2，pdt=(t1-t3)/5；
etu=t3，pdt=（t1-t3）/15；
……..
本実施例として別の1種の方式として選択t 1オプションを実施し、第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1唯一は、etuとpdtの値に応じてt 1の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=t1/5；
etu=2*t1，pdt=t1/10；
etu=t1/2，pdt=t1/5；
etu=t1/3，pdt=t1/15；
……..
本実施例として別の1種の方式として選択t0オプションを実施し、第一時間間隔組、ワインとして選択第一時間間隔組によって、一時間間隔組や第二時間間隔組確定当面データ伝送時間のパラメータは、パラメータの第1時間は参数時間を含むetuと第二時間パラメータpdt、etuとpdtはt0唯一とワインは、etuとpdtの値によるとt0ワインの値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t3/5；
etu=2*t0，pdt=t3/10；
etu=t0/2，pdt=t3/5；
etu=t0/3，pdt=t3/15；
etu=t0+t3，pdt=t0+t3/5；
etu=t0/3+t3，pdt=t0+t3/15；
……..
同様に、ときにK＝ななしち時、信号の2つの間に隣接するななしち共が生じるろく時間間隔がi＝にした時に１時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三つの信号開始時刻の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と五つ目の信号開始時刻の間の時間間隔ワインは、マークを；i＝ろく時から1時間の間隔を五つ目の信号と六番目の信号開始時刻の間の時間間隔で、表記をt4、第二時間の間隔を六番目の信号と七番目の信号開始時刻の間の時間間隔で、そのマークをt 5；、オプションをt0 t 2として、t4第一時間間隔組も選択t 1、ワインとt 5第二時間間隔組によって、一時間間隔組中の少なくとも2つの最初の時間間隔で確定当面データ伝送時間パラメータによって、第二時間間隔のグループに少なくとも二つの第二時間現在のデータ伝送の時間間隔確定パラメータも第一時間間隔のグループに少なくとも一時間間隔と第二時間間隔のグループに少なくとも1つの第二時間間隔共同確定当面データ伝送時間パラメータで、一時間間隔と第二時間間隔でない時間etuと隣接しており、パラメータpdtの取得方式は唯一、別の計算の方式を採用して、第一時間間隔組と/あるいは第二時間間隔組任意取得、具体的の取得方式を参考にできるK＝ごときの方案、これはもう贅言しない。
K＝さんが、さんの信号に隣接する2つの間の発生の時間間隔共に、ときに、i＝にした時に１時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三信号を開始時の間の時間間隔で、表記をt 1；これを例によって、以下のように一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間パラメータのやり方で詳細説明。
本実施例として別の1種の方式として選択t0オプションを実施し、第一時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0唯一は、etuとpdtの値によるとt0の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t0/5；
etu=2*t0，pdt=t0/10；
etu=t0/2，pdt=t0/5；
etu=t0/3，pdt=t0/15；
……..
本実施例として別の1種の方式として選択t 1オプションを実施し、第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1唯一は、etuとpdtの値に応じてt 1の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=t1/5；
etu=2*t1，pdt=t1/10；
etu=t1/2，pdt=t1/5；
etu=t1/3，pdt=t1/15；
……..
本実施例の中で上記の確定当面データ伝送時間パラメータの具体的な実施方式はサンプル的に実施する方式で、本申請に排除しない他の時間によってパラメータ生成規則第1時間間隔組中の少なくとも2つの最初の時間間隔で、または第二時間ぶりによって間のグループに少なくとも二つの第二時間間隔によって、あるいは第一時間間隔のグループに少なくとも一時間間隔や第二時間間隔のグループに少なくとも1つの第二時間間隔、確定当面データ伝送時間パラメータの実施方式。
本実施例第一時間間隔組と/あるいは第二時間間隔組を確定することetu時間パラメータとpdtことによって、保証データ伝送に毎回送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送前に受信側も送信側に送った握手情報は新たな時間パラメータetuとpdtの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と受信時間パラメータの違いは大きい時、受信側によるサンプリングたりして、受信エラー、通信効率低下の問題。
本実施例として1種のオプションの実施方法、もし一時間間隔と第二時間間隔満足満足しないデザイン関係上記デザイン関係は続行受信握手信号の手順は、すなわち戻ってステップS1801。
本実施例のデータ伝送の方法を通じて毎回受信データによる情報に握手は新たな時間のパラメータは、保証を送信側と受信側の時間パラメータ終始一緻、保証データの伝送の安定性とカラーを採用し、信号パルス信号を伝負けやすいと雑音信号を分けて、すべての信号の上昇を検出するまたは下落沿いに沿って、容易に得るすべての信号の開始時、それによって正確に隣接する2つの信号を開始時の間の時間間隔にの時間間隔を判断信号間の時間間隔を満たすかどうか判断デザイン関係、届いた信号を有効かどうかの握手信号で、正確に判断過程迅速で、かつ高い成功率によって、一時間間隔と/あるいは第二時間間隔確定第1時間間隔組と/あるいは第二時間間隔組を一時間間隔組と/あるいは第二時間間隔組を確定することetu時間パラメータとpdtことによって、保証データ伝送に毎回送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送前に受信側も送信側に送った握手情報は新たな時間パラメータetuとpdtの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と次の収時間パラメータの差がとても大きい時、受信側によるサンプリングずれ、受信エラー、通信効率の技術問題。

実施例15
本実施例1種数を提供する方法によるとじゅうく伝送、図の通り、本実施例のデータ伝送方法は主にステップS1901からステップS1903。
ステップS1901：確定時間パラメータ。
本実施例としての中で一種のオプションの実施方法、時間のパラメータは第一時間パラメータと/あるいは第二時間パラメータは、説明を容易にするために、本実施例の中将の第1時間は覚えetuパラメータは、第二時間パラメータ記をpdt、第一時間パラメータetuと第二時間パラメータpdt均代表時間の値を、例えばetu＝コンマ１秒、pdt＝0 . 01秒、値はデータを送信側と協議して受信側、この時間のパラメータは握手の時間間隔を確定する信号送信受信側によると、受信信号の握手を確定して、もちろん、時間だけで1パラメータも多く時間のパラメータは、本実施例で説明を例に持ち、だけで時間のパラメータを例にして、利用に時間のパラメータ確定第一時間間隔組や第二時間間隔組だが、多くの時間を排除しないパラメータの場合。
手順通りによってS1902：時間一時間間隔パラメータ確定組目と２時間間隔組。
その中に、第時間間隔を含む第一組j時間間隔で、第二時間間隔組を含むj二時間間隔として本実施例の中で1種のオプションの実施の形態、第一時間間隔は、送信Kの握手信号の時、ｉ番目の信号の始まりと第i-1信号の始まり時の間の時間間隔で、Ti-1覚えたり、i、第二時間間隔は、送信Kの握手信号の時、ｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔で、Ti覚えたり、i+1、中に、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
本実施例で説明が必要なことは、まず第一時間間隔組の中の第一時間間隔Ti-1、iと第二時間間隔組の中の第二時間間隔Ti、i+1一定のデザインとの関係を通じて、デザイン関係の有効性を保証することができて握手信号を受信側で受信この握手信号の後には、第一時間間隔Ti-1、iと第二時間間隔Ti、i+1のデザイン関係、判断し握手信号用指示から受信データの信号です；その次、第一時間間隔組の中の各一時間間隔Ti-1、iと第1時間パラメータetuおよび/または第二時間パラメータpdt一定のデザイン関係は、受信側では受信信号によって、握手した後、同じデザイン関係を通じて、受信した多くの最初の時間間隔計算第1時間パラメータe戒めと/あるいは第二時間pdtなパラメータを受信側によって第一時間パラメータetuおよび/または第二時間パラメータ計算をpdt伝送の時間間隔で対応ビットデータ。
本実施例では、１時間間隔組の中の第一時間間隔Ti-1、iと第二時間間隔組の中の第二時間間隔Ti、i+1一定のデザイン関係を含む可能の多くの種類、第一時間間隔組の中の各一時間間隔Ti-1、i 1時の間etuとパラメータ/または第二時間パラメータpdt一定のデザイン関係もいろいろに含む、以下、サンプル的な方法を説明する。
本実施例の一つとしてのオプションの実施の形態は、K＝ごを例にして、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔T 1、には第一個の信号と二番目の信号開始時刻の間の時間間隔で、マークをt0、第二時間間隔T 2、さんを第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間間隔Ｔ３、よんしよを三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔にチーム、ごを第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワイン。この時、t0、t 2第1時間間隔組を取って、t 1、ワインを第二時間間隔組、第一時間間隔と第二時間間隔の間を満たしデザイン関係いわゆる、t0とt 1の間で、ワインの間やt 2と共に満足デザイン関係によって、このデザイン関係の技術者の経験を確定して、あるいは実際に実行時のパラメータを確定する。つのオプションの実施方法として、デザイン関係をt 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2 ;や、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、その中で、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種類、ここはもう贅言。
以下、第一時間間隔組の第一時間間隔t0とt 2を例として、第一時間間隔組の中の各一時間間隔Ti-1、i t0、t 2と第1時間パラメータetuおよび/または第二時間パラメータpdt一定のデフォルトの関係を説明する：
第一時間間隔t0 t 2によると、一時間パラメータetuや第二時間パラメータpdt中の通過預設の時間パラメータ生成ルール生成をetuを例にして、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインのパラメータを生成時間ルールに限らない以下の計算の方式：
t0= a*etu;
t2 =x*a*etu；
その中で、aはですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するetu t 2。
あるいは、一時間間隔t0 t 2によると、一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下計計算方式：
t0= a*etu+b*pdt;
t2 =x*a*etu+b*pdt；
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するとpdt etu t 2。
あるいは、一時間間隔t0 t 2によると、一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下計計算方式：
t0= a*etu+b*pdt;
t2 = a*etu+ x*b*pdt；
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するとpdt etu t 2。
同様に、K=7の時、7つの信号が２つの間を隣り合って共に6つの時間間隔が発生するのが、i=2の時、第1時間間隔T1、2は1つ目の信号と2つ目の信号のために時間の間の時間間隔を始めて、0標記してtになって、第2時間間隔T2、3は2つ目の信号と3つ目の信号のために時間の間の時間間隔を始めて、1標記してtになります；i=4の時、第1時間間隔T3、4は3つ目の信号と4つ目の信号のために時間の間の時間間隔を始めて、2標記してtになって、第2時間間隔T4、5は4つ目の信号と5つ目の信号のために時間の間の時間間隔を始めて、3標記してtになります；i=6の時、第1時間間隔T5、6は5つ目の信号と6つ目の信号のために時間の間の時間間隔を始めて、4標記してtになって、第2時間間隔T6、7は6つ目の信号と7つ目の信号のために時間の間の時間間隔を始めます、標記をt 5；この時、t0、t 2とt4を一時間間隔組、t 1、ワインとt 5第二時間間隔組、第二時間間隔組のt 1、ワインとt 5と一時間間隔組のt0、t 2とt4それぞれ満足デザイン関係、つまりt0との間で、t 1 t 2とワインの間や、t4 t 5の間と共に満足デザイン関係によって、一時間パラメータetuおよび/または第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール確定第一時間間隔組の最初の時間間隔t0、t 2とt4の値を通じて、デザインのルールを採用して違う時間パラメータ生成の方式は、例えば、一時間間隔t0、t 2とt4、第一時間パラメータetuや第二時間パラメータpdt中の通過預設の時間パラメータ生成ルール生成をetuを例にして、t0、t 2とt4採用以下のいずれかの計算の方式を獲得するもちろん、デフォルトの時間パラメータ生成規則は以下の計算方式に限らない：
t0= a*etu;
t2 =x*a*etu；
t4=2x*a*etu；
その中で、aはですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetu。
あるいは、一時間間隔t0、t 2とt4、第一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0、t 2、t4採用以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下の計算の方式：
t0= a*etu+b*pdt;
t2 =x*a*etu+b*pdt；
t4=2x*a*etu+b*pdt；
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetuとpdt。
あるいは、一時間間隔t0、t 2とt4、第一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0、t 2とt4採用以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下の計算の方式：
t0= a*etu+b*pdt;
t2 = a*etu+ x*b*pdt；
t4= a*etu+2 x*b*pdt；
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetuとpdt。
本実施例の中で上記の確定当面データ伝送の最初の時間間隔組や第二時間間隔組の具体的な実施方式はサンプル的に実施する方式で、本申請に排除しない他の時間によってパラメータ生成規則第1時間パラメータetuおよび/または第二時間パラメータpdt確定第一時間間隔組の最初の時間間隔実施方式も排除しないで、他の最初の時間間隔と第二時間間隔のデフォルトの関係。
本実施例通過時間パラメータetuおよび/またはpdtする第一時間間隔組、それによって保証毎回データ伝送に送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送前に送信側も送った握手は新たな情報時間etuとpdtパラメータの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と受信時間パラメータの違いは大きい時、受信側によるサンプリングたりして、受信エラー、通信効率低下の問題。
ステップS1903：発生送信をKの握手信号。
本実施例のオプションとして1種の方式で実施し、具体的な実施にあたって、発生送信をKの握手が含まれます：第1時間によって信号間隔組目と２時間間隔組発生送信をKの握手信号；その中、Kの握手信号の中の第一時間間隔と第二時の間の間隔の間を満たし上記デフォルトの関係。
本実施例の中で、Kをあらかじめ設定値です、KさんでKは奇数で、信号を受信パルス信号、つまり高レベルパルス信号（上昇に沿って信号）、あるいは低レベルパルス信号（下がりに沿って信号）、パルス信号は方形波、正絃波、三角波や他の不規則波形は、上記の組み合わせによって波形。
本実施例では、K個の信号を発生して送信し、以下のように少なくとも1つを含む：
方式1：K次低レベルパルスを発生させる、
この方式では、高レベルで送信側は連続トリガK回低レベルパルスは、例えば、高レベルの最初の時間間隔がトリガー後、トリガいち度ローレベルパルス、そして再び回復トリガ高レベルの状態を経て、第二時間間隔の後は、トリガいち度低い電平パルスこのような方式を連発K回低レベルパルス、一時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔はｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔そのうち、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワインで高レベルで送信側連続トリガご回低レベルパルス、：続いてトリガ高レベルのしばらくの時間の後、トリガ第いち度ローレベルパルス、そして再び回復トリガ高レベルの状態を経て、t0後、第2回に低電気トリガ平パルス、そして再び回復トリガ高レベルの状態を経て、t 1後、トリガ第さん度ローレベルパルス、そして再び回復トリガ高レベルの状態を経て、t 2後、トリガ第よんしよ度ローレベルパルス、そして再び回復トリガ高レベルの状態を経て、ワインの後、触発第ご回低レベルパルスは、このような方式を連発ご回低レベルパルス、かつ、第一時間間隔と第二時間間隔満足デザイン関係、例えば、t 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2；あるいは、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、そのうち、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種の、ここでもう贅言を形成し、有効な握手信号、
方式2：K回高レベルパルスを発生させる、
この方式では、送信側で低水準にトリガK回高レベルパルスは、例えば、低レベルの最初の時間間隔がトリガー後、トリガいち度高いレベルパルス、そして再び回復トリガローレベルの状態を経て、第二時間間隔の後は、トリガいち度高い電平パルスこのような方式を連発K回高レベルパルス、一時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔はｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔そのうち、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワインを送信側は連続低レベルにトリガご回高レベルパルス、：続いてトリガ低レベルのしばらくの時間の後、トリガ第いち度高いレベルパルス、そして再び回復トリガローレベルの状態を経て、t0後、第2回に高い電気トリガ平パルス、そして再び回復トリガローレベルの状態を経て、t 1後、トリガ第さん度高いレベルパルス、そして再び回復トリガローレベルの状態を経て、t 2後、トリガ第よんしよ度高いレベルパルス、そして再び回復トリガローレベルの状態を経て、ワインの後、触発第ご回高レベルパルスは、このような方式を連発ご回高レベルパルス、かつ、第一時間間隔と第二時間間隔満足デザイン関係、例えば、t 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2；あるいは、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、そのうち、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種の、ここでもう贅言を形成し、有効な握手信号、
上記の方式で、Kの信号は跳ね上がる信号、しかも跳ね上がる幅は明らかに、便利と雑音信号を分けて。

実施例16
本実施例のデータ処理設備を提供し、図にじゅうの通り、このデータ処理設備を含める：受信モジュール、判断モジュール、時間処理モジュールとデータ処理モジュール。
受信モジュールは、Kの信号を受信するために使用されています。
Kをあらかじめ設定値、Kさんは奇数でKです、例えばプリセットK＝ご、受信モジュールご累計受信信号の場合、判断モジュール、時間処理モジュールとデータ処理モジュールにご受信信号処理し、本実施例のデータ処理装置を通じて同Kの信号の間の時間間隔の関係から判断できるかどうかを受信データ、つまり、もし満足デザイン関係はKの信号の後から受信データは、このKの信号として指示から受信データの握手信号；その中、信号がパルス信号を受信と、つまり高レベルパルス信号（上昇に沿って信号）、あるいは低レベルパルス信号（下がりに沿って信号）、パルス信号は方形波、正絃波、三角波や他の不規則波形は、上記の違い波形の組み合わせ。
本実施例において、受信モジュールは、K個の信号を受信するために、以下のように少なくとも1つを含む：
方式1：受信モジュールはK次低レベルパルスに検出された、
この方式では、受信モジュールを検出することができる高レベルでの連続K回低レベルパルスは、例えば、受信モジュール測定高レベルのしばらくの時間の後、検出いち度ローレベルパルス、そしてまた高レベルの状態まで回復検査を経て、しばらくの時間以降に、またいち検出回低レベルパルス、受信モジュールなどの方法で連続測定できるKまで度ローレベルパルス、
方式2：受信モジュールはK次高レベルのパルスまで検出された、
この方式では、受信モジュール検出できる連続ローレベル中のK回高レベルパルスは、例えば、受信モジュール測定、低レベルのしばらくの時間の後、検出いち度高いレベルパルス、そして再び回復低レベル検出の状態を経て、しばらくの時間以降に、またいち検出度の高いレベルパルス、受信モジュールなどの方法で連続測定できるKまで度高いレベルパルス、
上記の方式で、Kの信号は跳ね上がる信号、しかも跳ね上がる幅は明らかに、便利と雑音信号を分けて。
判定モジュールは、Kの信号の中に隣接する2つの間の時間間隔を検出するために使用される、
本実施例では、受信モジュール連続K信号受信後、判断モジュール検出K信号に隣接する2つの信号の間の時間間隔で、オプションにが、Ｋの信号を連続高レベルでのKの低レベルの信号の時、判断モジュール確定第p低電気普通郵便番号の開始時から第p+1低レベルの信号の開始時の間の時間は第pと第p+1信号の間の時間間隔で、同様にが、Ｋの信号を連続低レベルの高レベルの信号にK、判断モジュール確定第p高レベルの信号の開始時に刻から第p+1高レベルの信号の開始時の間の時間は第pと第p+1信号の間の時間間隔で、その、いち≦p≦K - 1、しかもp自然数として1種のオプションの実施の形態、判断を通じて各モジュール測定パルス信号の始まり隣接する2つの信号開始時刻の時間間隔を正確に迅速に取得する。
判断に判断モジュールは、第1時間間隔と第二時間間隔との間には満足デザイン関係。
本実施例として1種のオプションの実施の形態、第一時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔はｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔で、その中、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです；サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、マークをt 2、第二時間間隔が第4号と手紙第ご信号開始時刻の間の時間間隔で、表記はワイン。判断の第1時間間隔と第二時間間隔との間にはいわゆる満足デザイン関係、と判断t0 t 1の間や、t 2とワインとの間には共に満足デザイン関係によって、このデザイン関係の技術者の経験を確定して、あるいは実際に実行時のパラメータかも確かに限り、保証が満たされるというデザイン関係確かにこのKの信号を指示から受信データの握手信号。つのオプションの実施方法として、デザイン関係をt 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2 ;や、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、その中で、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種類、ここはもう贅言；判断モジュール判定第一時間間隔と第二時間間隔満足デザイン関係の時、すぐ判定K信号を有効に握手信号。
時間処理モジュール用に、確定第一時間間隔組と/あるいは第二時間間隔組、第一時間間隔を含む第一組j時間間隔で、第二時間間隔組を含むj二時間間隔、j＝（K - 1）/に、Kさんは奇数でKです。
iを取ることがないまた、時間によって処理モジュールK信号発生のK - 1時間間隔を生むシリーズの第一時間間隔と第二時間間隔で、時間処理モジュールから複数の異なるの最初の時間間隔で選択少なくともいちになって第一時間間隔組が、同様に、時間も処理モジュール複数の異なる第二時間間隔を選んで少なくともいちの第二時間間隔組、例えば、K＝ごとき、ご信号発生間隔で第1時間t0、t 2、および第二時間間隔t 1、ワインはこの時、時間がt0処理モジュールを取り、t 2として第一時間間隔組を取って、t 1、ワインは第二時間間隔組、本実施例のは限界第一時間間隔組や第二時間間隔組中時間間隔の数は、全てｊ、少なくとも1つの時間で、処理モジュール通この方式を決定することができます第一時間間隔組と/あるいは第二時間間隔組、ように時間間隔を分類して処理する。
もし一時間間隔と第二時間間隔満足デザイン関係、時間処理モジュールは第一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間参数、
そのうち、時間によって処理モジュールは第一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間のパラメータは、具体的には、時間によって処理モジュール第一時間間隔組中の少なくとも2つの第1時間は間隔によって、または第二時間間隔のグループに少なくとも二つの第二時間間隔で、または第一時間間隔のグループに少なくとも一時間間隔や第二時間間隔のグループに少なくとも1つの第二時間間隔に応じておくと、データを送信側が約束の時間パラメータ生成ルール、かつ第一時間間隔と第二時間間隔は隣接する。
本実施例では、確定した第一時間間隔組や第二時間間隔組で、そのｉ番目の信号と第i-1信号の間の最初の時間間隔とｉ番目の信号と第i+1信号の間の第二時間間隔は満足デザイン関係の時、Kの信号を判定有効な握手信号は、この時、時間によって処理モジュール第一時間間隔組中の少なくとも2つの最初の時間間隔によって、または第二時間間隔のグループに少なくとも二つの第二時間間隔で、または第一時間間隔のグループに少なくとも一時間間隔や第二時間間隔のグループに少なくとも一つ第二時間間隔に応じておくと、データを送信側が約束の時間パラメータ生成ルール、かつ第一時間間隔と第二時間間隔は隣接しており、確定当面データ伝送時間パラメータ、そのうち、あらかじめ約束の時間はすべてパラメータ生成ルール保証データビット符号化方式の唯一の前提の下で、任意の種類の方式を選ぶことができる時間をパラメータの確定。
例えば、私K＝ごとき、ごの信号に隣接する2つの間の発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三つの信号開始時刻の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔ワインは、マークは、これを例にして、次に第一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間パラメータのやり方の詳細。
本実施例の一つとしてのオプションの実施方法、時間処理モジュールt0として選択t 2第1時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0とt 2唯一は、etuとpdtの値によるとt0 t 2の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=（t0-t2）/5；
etu=t0+t2，pdt=（t0+t2）/10；
etu=t0+t2/2，pdt=(t0-t2)/5；
etu=t2，pdt=（t0-t2）/15；
……..
本実施例として別の1種のオプションの実施方法、時間処理モジュールとして選択t0第一時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0唯一は、etuとpdtの値がt0の値によって任意計算の方式を通じて獲得する性の、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t0/5；
etu=2*t0，pdt=t0/10；
etu=t0/2，pdt=t0/5；
etu=t0/3，pdt=t0/15；
……..
本実施例として別の1種のオプションの実施方法、時間処理モジュール選択取t 1とワインは第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1とワインは唯一の表示、etuとpdtの値によるとワインの値を通じてt 1任意計算方を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=（t1-t3）/5；
etu=t1+t3，pdt=（t1+t3）/10；
etu=t1+t3/2，pdt=(t1-t3)/5；
etu=t3，pdt=（t1-t3）/15；
……..
本実施例として別の1種のオプションの実施方法、時間処理モジュール選択取t 1第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1唯一は、etuとpdtの値に応じてt 1の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=t1/5；
etu=2*t1，pdt=t1/10；
etu=t1/2，pdt=t1/5；
etu=t1/3，pdt=t1/15；
……..
K＝さんが、さんの信号に隣接する2つの間の発生の時間間隔共に、ときに、i＝にした時に１時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三信号を開始時の間の時間間隔で、表記をt 1；これを例によって、以下のように一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間パラメータのやり方で詳細説明。
本実施例として別の1種の方式として選択t0オプションを実施し、第一時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0唯一は、etuとpdtの値によるとt0の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t0/5；
etu=2*t0，pdt=t0/10；
etu=t0/2，pdt=t0/5；
etu=t0/3，pdt=t0/15；
……..
本実施例として別の1種の方式として選択t 1オプションを実施し、第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1唯一は、etuとpdtの値に応じてt 1の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=t1/5；
etu=2*t1，pdt=t1/10；
etu=t1/2，pdt=t1/5；
etu=t1/3，pdt=t1/15；
……..
同様に、ときにK＝ななしち時、信号の2つの間に隣接するななしち共が生じるろく時間間隔がi＝にした時に１時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三つの信号開始時刻の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と五つ目の信号開始時刻の間の時間間隔ワインは、マークを；i＝ろく時から1時間の間隔を五つ目の信号と六番目の信号開始時刻の間の時間間隔で、表記をt 5、第二時間の間隔を六番目の信号と七番目の信号開始時刻の間の時間間隔で、そのマークをt6；時間がt0選び処理モジュール、t 2として第一時間間隔t 5組も選択t 1、ワインとt6第二時間間隔組、時間によって処理モジュール第一時間間隔組中の少なくとも2つの最初の時間間隔で確定当面データ伝送時間パラメータによって、第二時間間隔のグループに少なくとも二つの第二時間間隔確定当面データ伝送時間パラメータも第一時間間隔のグループに少なくとも一時間間隔と第二時間間隔のグループに少なくとも1つの第二時間間隔共同確定当面データ伝負け時間パラメータ、かつ第一時間間隔と第二時間間隔隣接する時間がない、パラメータetuとpdtの取得方式は唯一、時間処理モジュールを採用して別の計算の方式を通じて一時間間隔組と/あるいは第二時間間隔組任意獲取って、具体的に取得する方法はK = 5時の案を参考にすることができて、ここではもう言及しない。
K＝さんが、さんの信号に隣接する2つの間の発生の時間間隔共に、ときに、i＝にした時に１時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と第三信号を開始時の間の時間間隔で、表記をt 1；これを例によって、以下のように一時間間隔のグループに少なくとも一時間間隔と/あるいは前記第二時間間隔のグループに少なくとも1つの第二時間間隔確定当面データ伝送時間パラメータのやり方で詳細説明。
本実施例として別の1種の方式として選択t0オプションを実施し、第一時間間隔組によって、一時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt0唯一は、etuとpdtの値によるとt0の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t0，pdt=t0/5；
etu=2*t0，pdt=t0/10；
etu=t0/2，pdt=t0/5；
etu=t0/3，pdt=t0/15；
……..
本実施例として別の1種の方式として選択t 1オプションを実施し、第二時間間隔組によって、第二時間間隔組確定当面データ伝送の時間の時間を含むパラメータは、パラメータ第1時間パラメータetuと第二時間パラメータpdt、etuとpdtはt 1唯一は、etuとpdtの値に応じてt 1の値を任意計算の方式を獲得し、サンプル性、etuとpdt採用以下のいずれかの計算の方式を獲得し、もちろん、限らず以下の計算の方式：
etu=t1，pdt=t1/5；
etu=2*t1，pdt=t1/10；
etu=t1/2，pdt=t1/5；
etu=t1/3，pdt=t1/15；
……..
本実施例の中で上記の確定当面データ伝送時間パラメータの具体的な実施方式はサンプル的に実施する方式で、本申請に排除しない他の時間によってパラメータ生成規則第1時間間隔組中の少なくとも2つの最初の時間間隔で、または第二時間ぶりによって間のグループに少なくとも二つの第二時間間隔によって、あるいは第一時間間隔のグループに少なくとも一時間間隔や第二時間間隔のグループに少なくとも1つの第二時間間隔、確定当面データ伝送時間パラメータの実施方式。
本実施例の中で時間処理モジュール第一時間間隔組と/あるいは第二時間間隔組を確定することetu時間パラメータとpdtことによって、保証データ伝送に毎回送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送の前に受信側も送信側に送った握手情報は新たな時間パラメータetuとpdtの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と受信時間パラメータの違いは大きい時、受信側によるサンプリングたりして、受信エラー、通信効率の問題。
本実施例として1種のオプションの実施方法、もし一時間間隔と第二時間間隔満足満足しないデザイン関係上記デザイン関係、と指示を受け続けて握手信号を受信モジュール。
データ処理モジュールは、時間パラメータによってデータを受信する。
本実施例として1種のオプションの実施の形態、受信モジュールは、受信用X信号確定X信号に隣接する2つの信号のスタート時の間の時間間隔で、得X-1時間間隔で、その中、Xは正整数で、X＞いち；データ処理モジュールは、通りに時間パラメータ受信このX信号、具体的に、データ処理、モジュールを得るために、X-1時間間隔で各連続Sの時間間隔で1時間間隔対応のNデータビットを得て、Sの時間間隔伝送のデータビット、得たのSの時間間隔伝送のデータビットを取得するためのNデータビット、その中で、S＞いちの情況の下で、Sの時間間隔が同じで、そのうち、XとSはすべて正整数で、S X-1≦。
本実施例として1種のオプションの実施の形態、データ入手が受信側採用とデータの送信側の計算方法によって協議して現在のデータ伝送時間パラメータ確定データビット、現在データ受信側と協議してデータを送信側の計算方法を、ときに、N＝n時、送信データビットmの時間間隔の計算方法をm＝etu+m * pdt（中には、0 m≦≦2n-1、etuを一時間パラメータ、pdt第二時間パラメータ、etu＝じゅうμs、pdt＝さんじゅうμs）、すなわちデータビットじゅういちの時間間隔で計算方法をじゅうμs+3 *さんじゅうμs＝ひゃくμs。もしデータ受信装置を受信ひゃくμsの時間間隔で、計算mをさん、すなわち同時間間隔に対応するデータビットをじゅういち。
本実施例として1種のオプションの実施方法によって、データ処理モジュールの第1時間はパラメータetuと第二時間パラメータpdtとデータの送信側にあらかじめ約束の暗号化／復号化ルールを受信データ;データ処理モジュールに時間を含むパラメータ受信データに基づいてのように時間をNビットデータのパラメータを含め2Nつの異なる数値と時間間隔の対応関係、中に、異なる数値対応の時間間隔と違って、そのうち、Nですいち。
データ処理モジュール第一時間パラメータetuと第二時間パラメータpdtとデータの送信側にあらかじめ約束の暗号化／復号化ルールを含め、Nビットデータの2N数値と違う時間間隔の対応関係、あらかじめ約束の暗号化／復号化ルールが保険証を異なる数値のNデータビット対応唯一時間間隔の任意の方式、サンプル的に：
N = 1の場合、異なる数値のN個のデータビットは、0、1、この時、
0＝etu、いち＝etu+pdt、しかもetu≠etu+pdt、または、
0＝2etu、いち＝etu+2pdt、しかも2etu≠etu+2pdt、
……
N = 2の場合、異なる数値のN個のデータビットは、00、01、10、11に含まれている、
00＝etu、01＝etu+pdt、じゅう＝etu+2pdt、じゅういち＝etu+3pdt、しかもetu≠etu+pdt≠etu+2pdt≠etu+3pdt、または、
00＝2etu、01＝etu+2pdt、じゅう＝etu+2.5pdt、じゅういち＝1.3etu+3pdt、
しかも2etu≠etu+2pdt≠etu+2.5pdt≠1.3etu+3pdt、
……
同様に、ときにN＝さんに、異なる数値データビットが含まれます：N 001、000、010、2011、ひゃく、101、110、111、この時、第一時間パラメータetuと第二時間パラメータpdtとデータの送信側にあらかじめ約束の暗号化／復号化ルールを得て、Nビットデータかばんを含むの2N異なる数値対応の時間間隔で、あらかじめ約束の暗号化／復号化ルールを上記サンプル、ここでもう贅言。
データ処理モジュールとデータの送信側にあらかじめ約束の方式によって、一時間パラメータetuと第二時間pdt Nビットデータを含むパラメータの2N異なる数値対応の時間間隔で、その中、異なる数値対応の時間間隔違うことによって、分けて受信の別の時間間隔に対応した異なるデータビットを通じて、実現の時間間隔を受信して送信側のデータ送信。
本実施例のオプション実施方式では、時間の処理モジュールは、されているデータ処理モジュールを送信したデータを前に、時間が異なる数値にパラメータのNビット対応の時間間隔で、その中、異なる数値のNビット対応の時間間隔でないと、Nいちです、

オプションにデータを採用し、受信側と協議してデータを送信側の計算方法とデータビット計算の時間間隔のときのようなN＝n、送信データビットmの時間間隔の計算方法をm＝etu+m * pdt（中には、0 m≦≦2n-1、etuを一時間パラメータ、pdt第二時間パラメータ、etu＝じゅうμs、pdt＝さんじゅうμs）、すなわちデータビットじゅういちの時間間隔で計算方法をじゅうμs +さん*さんじゅうμs＝ひゃくμs、他の事前協議を採用することができるの計算方法確定時間間隔、本実施は具体的に制限しない。事前協議を通じての計算方法を算出するこのデータビットの時間間隔で、保証データの伝送の拡張性、すなわちどんなにNのことはいくらで、データを送信側とデータ受信側も計算データビットの時間間隔。
本申請の実施例としての別のオプション実施方式。データ受信側も採用とデータの送信側あらかじめメモリーのリストを確定することもこのデータビットの時間間隔で、データ処理モジュールを採用して検索リストの方が固まっこのデータビットの時間間隔を得、データビット時間間隔の効率。
本実施例のオプション実施方式では、X-1＝n * S、nですいちかつnを整数を採用し、このオプション実施方式、X信号伝送n * Sまた同じことができるデータビットではないが、余分な信号による復号化問題ない。
本実施例のオプション実施方式では、図きゅう、く通り、データ処理設備更新時間パラメータも含め、モジュール用交換時間パラメータ、すなわち規則に預設を当面使用時間パラメータに代える新しい時間パラメータは、新しい時間参数として当面データ伝送時間パラメータ;データ処理モジュールは、再取得の違いによって用数値のNビット対応の時間間隔では受信X信号で復号化し、すなわち現在に使う時間パラメータをX-1時間間隔で各連続Sの時間間隔で1時間間隔対応のNビットを得て、S時間間隔伝送のデータビット、得たのSの時間間隔伝送のデータを取得するためのNビットビット。本実施案では、新しい時間パラメータの確定することを通じてデータを送信側との協議の完成データ受信側も、データを送信側とデータ検索あらかじめメモリー受信側の時間パラメーターリストを完瞭するなど、発送にあるタイプでデータを表確定タイプのデータを使用するべきである時間のパラメータ。データ送信側の時間パラメータは変化が一緻することができますによって、データ処理能力のデータを受信装置、または一緻の異なるタイプのデータを、データ処理の効率を向上させ。
本実施例のオプション実施方式では、受信モジュールは、完成されている受信最後のデータビット後は、受信できるAが信号（Zですいちしかも整数）、終瞭信号と同じ握手信号は、他の特定のフォーマットの信号は、同終瞭信号、データ処理できるかどうか判断モジュールデータビット受信終瞭。
本実施例のオプション実施方式では、受信モジュールは、完成されている受信最後のデータビットの後、または完成受信Aが信号を受信後、モジュールは、受信用検査データビットは、同検査データビット、完全に正しいかどうか判断受信データ。検査データビットは、MAC検査、パリティ、取と検査などパリティ方式で計算した検査データ。
本実施例のオプション実施方式では、図きゅう、く通り、データ処理設備も含むフィルターモジュール用の信号を受信Z、Zの信号の妨害を得て、X信号送信をから受信モジュールのうち、ZですX。
この本申請実施例が提供した技術方案を見抜くことができて、データ処理モジュールによって受信波形の時間間隔で確定受信波形データビット、二線だけを使用して完成のデータを受信し、電子機器に適用した時に、効果的に電子機器の体積は小さく。
本実施例のデータ処理モジュールを通じて毎回受信データによる情報に握手は新たな時間のパラメータは、保証を送信側と受信側の時間パラメータ終始一緻、保証データの伝送の安定性とカラーを採用し、信号パルス信号を伝負けやすいと雑音信号を分けて、すべての信号の上昇を検出するまたは下落沿いに沿って、容易に得るすべての信号の開始時、それによって正確に隣接する2つの信号を開始時の間の時間間隔にの時間間隔を判断信号間の時間間隔を満たすかどうか判断デザイン関係、届いた信号を有効かどうかの握手信号で、正確に判断過程迅速で、かつ高い成功率によって、一時間間隔と/あるいは第二時間間隔確定第1時間間隔組と/あるいは第二時間間隔組を一時間間隔組と/あるいは第二時間間隔組を確定することetu時間パラメータとpdtことによって、保証データ伝送に毎回送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送前に受信側も送信側に送った握手情報は新たな時間パラメータetuとpdtの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と次の収時間パラメータの差がとても大きい時、受信側によるサンプリングずれ、受信エラー、通信効率の技術問題。

実施例17
本実施例のデータ処理設備を提供し、図１に示すように、このデータ処理設備を含む：第二時間パラメータモジュール、第二時間処理モジュール、第二信号発生発送モジュール。
その中で、第2時間パラメータモジュールは、時間パラメータを確定するために使用されています。
本実施例としての中で一種のオプションの実施方法、時間のパラメータは第一時間パラメータと/あるいは第二時間パラメータは、説明を容易にするために、本実施例の中将の第1時間は覚えetuパラメータは、第二時間パラメータ記をpdt、第一時間パラメータetuと第二時間パラメータpdt均代表時間の値を、例えばetu＝コンマ１秒、pdt＝0 . 01秒、値はデータを送信側と協議して受信側、この時間のパラメータは握手の時間間隔を確定する信号送信受信側によると、受信信号の握手を確定して、もちろん、時間だけで1パラメータも多く時間のパラメータは、本実施例で説明を例に持ち、だけで時間のパラメータを例にして、利用に時間のパラメータ確定第一時間間隔組や第二時間間隔組だが、多くの時間を排除しないパラメータの場合。
前記第二時間処理モジュール用に、前記第一時間によるパラメータ確定時間間隔組目と２時間間隔組のうち、前記第一時間間隔を含む第一組j時間間隔で、前記第二時間間隔組を含むj二時間間隔。
本実施例としての中で一種のオプションの実施の形態、第一時間間隔は、第二信号発生発送モジュール発送Kの握手信号の時、ｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、Ti-1覚えたり、i、第二時間ぶりとは発送Kの握手信号の時、ｉ番目の信号の始まりと第i+1信号の開始時の間の時間間隔で、Ti覚えたり、i+1、中に、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
本実施例で説明が必要なことは、まず第一時間間隔組の中の第一時間間隔Ti-1、iと第二時間間隔組の中の第二時間間隔Ti、i+1一定のデザインとの関係を通じて、デザイン関係の有効性を保証することができて握手信号を受信側で受信この握手信号の後には、第一時間間隔Ti-1、iと第二時間間隔Ti、i+1のデザイン関係、判断し握手信号用指示から受信データの信号です；その次、第一時間間隔組の中の各一時間間隔Ti-1、iと第1時間パラメータetuおよび/または第二時間パラメータpdt一定のデザイン関係は、受信側では受信信号によって、握手した後、同じデザイン関係を通じて、受信した多くの最初の時間間隔計算第1時間パラメータe戒めと/あるいは第二時間pdtなパラメータを受信側によって第一時間パラメータetuおよび/または第二時間パラメータ計算をpdt伝送の時間間隔で対応ビットデータ。
本実施例では、１時間間隔組の中の第一時間間隔Ti-1、iと第二時間間隔組の中の第二時間間隔Ti、i+1一定のデザイン関係を含む可能の多くの種類、第一時間間隔組の中の各一時間間隔Ti-1、i 1時の間etuとパラメータ/または第二時間パラメータpdt一定のデザイン関係もいろいろに含む、以下、サンプル的な方法を説明する。
本実施例の一つとしてのオプションの実施の形態は、K＝ごを例にして、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔T 1、には第一個の信号と二番目の信号開始時刻の間の時間間隔で、マークをt0、第二時間間隔T 2、さんを第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間間隔Ｔ３、よんしよを三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔にチーム、ごを第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワイン。この時、t0、t 2第1時間間隔組を取って、t 1、ワインを第二時間間隔組、第一時間間隔と第二時間間隔の間を満たしデザイン関係いわゆる、t0とt 1の間で、ワインの間やt 2と共に満足デザイン関係によって、このデザイン関係の技術者の経験を確定して、あるいは実際に実行時のパラメータを確定する。つのオプションの実施方法として、デザイン関係をt 1＝a * t0かつワイン＝a * t 2 ;や、t 1＝（a + b）* t0かつワイン＝（a + b）* t 2 ;や、t 1＝（c * a + b）* t0かつワイン＝（c * a + b）* t 2、その中で、a、b、cをですいちの自然数、例えば、a =に、同デザイン関係は多種類、ここはもう贅言。
以下、第一時間間隔組の第一時間間隔t0とt 2を例として、第一時間間隔組の中の各一時間間隔Ti-1、i t0、t 2と第1時間パラメータetuおよび/または第二時間パラメータpdt一定のデフォルトの関係を説明する：
第一時間間隔t0 t 2によると、一時間パラメータetuや第二時間パラメータpdt中の通過預設の時間パラメータ生成ルール生成をetuを例にして、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインのパラメータを生成時間ルールに限らない以下の計算の方式：
t0＝a * etu、
t 2＝x * a * etu、
その中で、aはですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するetu t 2。
あるいは、一時間間隔t0 t 2によると、一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下計計算方式：
t0＝a * etu+b * pdt、
t 2＝x * a * etu+b * pdt、
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するとpdt etu t 2。
あるいは、一時間間隔t0 t 2によると、一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0とt 2を採用して以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下計計算方式：
t0＝a * etu+b * pdt、
t 2＝a * etu + x * b * pdt、
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルールと計算するとpdt etu t 2。
同様に、K=7の時、7つの信号が２つの間を隣り合って共に6つの時間間隔が発生するのが、i=2の時、第1時間間隔T1、2は1つ目の信号と2つ目の信号のために時間の間の時間間隔を始めて、0標記してtになって、第2時間間隔T2、3は2つ目の信号と3つ目の信号のために時間の間の時間間隔を始めて、1標記してtになります；i=4の時、第1時間間隔T3、4は3つ目の信号と4つ目の信号のために時間の間の時間間隔を始めて、2標記してtになって、第2時間間隔T4、5は4つ目の信号と5つ目の信号のために時間の間の時間間隔を始めて、3標記してtになります；i=6の時、第1時間間隔T5、6は5つ目の信号と6つ目の信号のために時間の間の時間間隔を始めて、4標記してtになって、第2時間間隔T6、7は6つ目の信号と7つ目の信号のために時間の間の時間間隔を始めます、標記をt 5；この時、t0、t 2とt4を一時間間隔組、t 1、ワインとt 5第二時間間隔組、第二時間間隔組のt 1、ワインとt 5と一時間間隔組のt0、t 2とt4それぞれ満足デザイン関係、つまりt0との間で、t 1 t 2とワインの間や、t4 t 5の間と共に満足デザイン関係によって、一時間パラメータetuおよび/または第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール確定第一時間間隔組の最初の時間間隔t0、t 2とt4の値を通じて、デザインのルールを採用して違う時間パラメータ生成の方式は、例えば、一時間間隔t0、t 2とt4、第一時間パラメータetuや第二時間パラメータpdt中の通過預設の時間パラメータ生成ルール生成をetuを例にして、t0、t 2とt4採用以下のいずれかの計算の方式を獲得するもちろん、デフォルトの時間パラメータ生成規則は以下の計算方式に限らない：
t0= a*etu;
t2 =x*a*etu；
t4=2x*a*etu；
その中で、aはですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetu。
あるいは、一時間間隔t0、t 2とt4、第一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0、t 2、t4採用以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下の計算の方式：
t0＝a * etu+b * pdt、
t 2＝x * a * etu+b * pdt、
t4＝2x * a * etu+b * pdt、
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetuとpdt。
あるいは、一時間間隔t0、t 2とt4、第一時間パラメータetuと第二時間pdt預設のパラメータを通じて時間パラメータ生成ルール生成、t0、t 2とt4採用以下のいずれかの計算の方式を獲得し、もちろん、デザインに限らず時間パラメータ生成ルール以下の計算の方式：
t0＝a * etu+b * pdt、
t 2＝a * etu + x * b * pdt、
t4＝a * etu+2 x * b * pdt、
その中で、a、bをですいちの自然数、xを有理数ため、受信側を同じデザインの時間を利用してt0パラメータ生成ルール、t 2、t4計算するetuとpdt。
本実施例の中で上記の確定当面データ伝送の最初の時間間隔組や第二時間間隔組の具体的な実施方式はサンプル的に実施する方式で、本申請に排除しない他の時間によってパラメータ生成規則第1時間パラメータetuおよび/または第二時間パラメータpdt確定第一時間間隔組の最初の時間間隔実施方式も排除しないで、他の最初の時間間隔と第二時間間隔のデフォルトの関係。
本実施例通過時間パラメータetuおよび/またはpdtする第一時間間隔組、それによって保証毎回データ伝送に送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたびデータ伝送前に送信側も送った握手は新たな情報時間etuとpdtパラメータの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と受信時間パラメータの違いは大きい時、受信側によるサンプリングたりして、受信エラー、通信効率低下の問題。
第2信号による送信モジュールは、K個の握手信号を生成し送信する。
本実施例のオプションとして1種の方式で実施し、具体的な実施にあたって、発生送信をKの握手が含まれます：第1時間によって信号間隔組目と２時間間隔組発生送信をKの握手信号；その中、Kの握手信号の中の第一時間間隔と第二時の間の間隔の間を満たし上記デフォルトの関係も参照して実施例じゅうよんで一時間間隔と第二時間間隔を満たす必要のデザイン関係の説明。
本実施例の中で、Kをあらかじめ設定値です、KさんでKは奇数で、信号を受信パルス信号、つまり高レベルパルス信号（上昇に沿って信号）、あるいは低レベルパルス信号（下がりに沿って信号）、パルス信号は方形波、正絃波、三角波や他の不規則波形は、上記の組み合わせによって波形。
本実施例では、第二信号発生発送モジュール発生送信をKの信号を含む少なくとも一つは以下の方式：
方式1：第2信号による送信モジュールが発生してK次低レベルのパルスを送信する、
この方式では、第2信号発生発送モジュールが連続ハイレベルにトリガK回低レベルパルス、例えば、第二信号発生発送モジュール続いてトリガハイレベル第一時間間隔後、トリガいち度ローレベルパルス、そして再び回復トリガ高レベルの状態を経て、第二時間間隔後また、トリガいち度ローレベルパルスは、このような方式を連発K回低レベルパルス、一時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔とできるｉ番目の信号の始まりと第i+1つ信号の開始時の間の時間間隔で、その中、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワイン、第二信号発生発送モジュールが連続ハイレベルにトリガご回低レベルパルス、：第2信号発生発送モジュール続いてトリガ高レベルのしばらくの時間の後、トリガ第いち度ローレベルパルス、そして再び回復トリガ高い電の気の平らな状態、t0を通った後で、第2回の低レベルのパルスを触発して、それからまた高い電圧の状態を触発するのを回復して、t1を通った後で、第3回の低レベルのパルスを触発して、それからまた高い電圧の状態を触発するのを回復して、t2を通った後で、第4回の低レベルのパルスを触発して、それからまた高い電圧の状態を触発するのを回復して、t3を通った後で、第5回の低レベルのパルスを触発して、このような方法で連続して5回の低レベルのパルスが発生することができて、しかも、第1時間間隔と第2時間間隔はデフォルト関係を満足させて、例えば、t1=a*t0しかもt3=a*t2；あるいは、t1=（a+b）の*t0しかもt3=（a+b）の*t2；あるいは、t1=（c*a+b）の*t0しかもt3=（c*a+b）の*t2、その中、a、b、c≧1の自然数で、例えば、a=2，このデフォルト関係は多種であることができるで、このところはもうくどくど言わないで、有効なハンドシェイクを形成します；
方式2：第2信号による送信モジュールが発生してK次高レベルのパルスを送信する、
この方式では、第2信号発生発送モジュールが連続ローレベルでトリガK回高レベルパルス、例えば、第二信号発生発送モジュール続いてトリガローレベル第一時間間隔後、トリガいち度高いレベルパルス、そして再び回復トリガローレベルの状態を経て、第二時間間隔後また、トリガいち度高いレベルパルスは、このような方式を連発K回高レベルパルス、一時間間隔はｉ番目の信号の始まりと第i-1信号の開始時の間の時間間隔で、第二時間間隔とできるｉ番目の信号の始まりと第i+1つ信号の開始時の間の時間間隔で、その中、i＝に、よんしよ、……、2j、j＝（K - 1）/に、Kさんは奇数でKです。
サンプル性のが、Ｋ＝ごとき、ごの信号に隣接する2つの間ごとに発生の時間間隔でよんしよi＝になる時、第1時間間隔は第一個の信号と二番目の信号を開始時の間の時間間隔で、表記をt0、第二時間間隔を第2の信号と三つ目の信号を開始時の間の時間間隔で、表記をt 1 i＝よんしよ;とき時、第1時間の間隔を三つ目の信号と第4の信号開始時刻の間の時間間隔で、表記をt 2、第二時間間隔が第4の信号と第ご信号開始時刻の間の時間間隔で、表記はワイン、第二信号発生発送モジュールが連続ローレベルでトリガご回高レベルパルス、：第2信号発生発送モジュール続いてトリガ低レベルのしばらくの時間の後、トリガ第いち度高いレベルパルス、そして再び回復トリガ低電の気の平らな状態、t0を通った後で、第2回の高の電圧のパルスを触発して、それからまた低レベルの状態を触発するのを回復して、t1を通った後で、第3回の高の電圧のパルスを触発して、それからまた低レベルの状態を触発するのを回復して、t2を通った後で、第4回の高の電圧のパルスを触発して、それからまた低レベルの状態を触発するのを回復して、t3を通った後で、第5回の高の電圧のパルスを触発して、このような方法で連続して5回の高の電圧のパルスが発生することができて、しかも、第1時間間隔と第2時間間隔はデフォルト関係を満足させて、例えば、t1=a*t0しかもt3=a*t2；あるいは、t1=（a+b）の*t0しかもt3=（a+b）の*t2；あるいは、t1=（c*a+b）の*t0しかもt3=（c*a+b）の*t2、その中、a、b、c≧1の自然数で、例えば、a=2，このデフォルト関係は多種であることができるで、このところはもうくどくど言わないで、有効なハンドシェイクを形成します。
上記の方式で、Kの信号は跳ね上がる信号、しかも跳ね上がる幅は明らかに、便利と雑音信号を分けて。
毎回受信データによって握手を通じて前に情報は新たな時間のパラメータは、保証を送信側と受信側の時間パラメータ終始一緻、保証データの伝送の安定性と正確パルス信号伝送を採用して、信号を持ち、と雑音信号を分けて、すべての信号を検出トリガーの上昇または減少沿いに沿って、容易に得ることができるすべての信号の開始時、それによって正確に隣接する2つの信号を開始時の間の時間間隔にの時間間隔を判断信号間の時間間隔は否満足デザイン関係、判断を受信信号を有効かどうかの握手信号、正確かつ迅速に判断する過程で、高い成功率による第一時間間隔と/あるいは第二時間間隔確定第一時間間隔組と/あるいは第二時間間隔組、を第一時間間隔組と/あるいは第二時間間隔組を確定することetu時間パラメータとpdtことによって、保証データ伝送に毎回送信側と、受信側にetuとpdtのことで一緻して、毎回データ伝送の安定性と正確性、たびたび数によると前によって受信側も伝送送信側の情報を送信握手は新たな時間パラメータetuとpdtの値を避け、週波数差が複数文字の連続加算による誤差累計、送信防止に有効に時計と受信時間パラメータの違いは大きい時、受信側によるサンプリングたりして、受信エラー、通信効率の技術問題。 According to the technical means provided by the above-described embodiment of the present invention, the data receiving apparatus can indicate the data of the received waveform at the time interval of the received waveform, and the reception of the data is completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.
Example 5
According to the flowchart of the genus transmission method of the present embodiment that provided the application shown in FIG. 10, this method mainly includes steps S901 to S903 as shown in FIG.
S901, first frequency information acquisition device, second frequency information transmission device.
Among them, this frequency information is used for new time parameter of data transmission, or new time parameter indicator, new time parameter indicator and new time parameter correspondence. In this new parameter, the possible time of 2 hours parameter, the first time, the parameter etu and the second time parameter pdt, in this application, the length of time occupied for data transmission applied to the same time parameter.
In this embodiment, the first device and the second device are mainly from facilities. Equipment mainly composed of the first device, equipment composed mainly of the second device, or equipment composed mainly of the first device and equipment mainly composed of the second device. As an apparatus of a main facility, for example, a terminal, for example, an apparatus from the facility is an electronic payment facility (for example, an electronic signature tool key, a smart card, a key card uniting facility, etc.).
S902, the new time parameter of the frequency information confirmation data transmission according to the frequency transmitter / receiver information of the second first device.
Among them, for example, a handshake signal is transmitted or a data signal is transmitted through various methods of transmitting frequency information from the second device to the second device. Depending on the transmission method adopting the frequency information, the new time parameter of the deterministic data transmission is different depending on the frequency information at this step, specifically refer to the specific description in the embodiment below.
S903, when supporting the second device for data transmission at a new time, according to the correspondence between each bit bit skewer and the time interval of 2N in the new time parameter new time parameter According to the correspondence relationship described above, the bit skewer corresponding to the time interval as acquired at the time interval in the transmission data signal or the data signal based on the new parameter reception data signal according to the time, of which the bit skewer is separate and different as 2N Unlike the time interval corresponding to the bit skewer, N is one.
For example, for N = 1 as an example, with 2N lengths of N bit bits, according to each skewer 0, 1, a new time parameter with a new time parameter 2N length of each bit bit skewer within N Possible correspondence including skew and time interval 0 = etu, 1 = etu + pdt, in which 0 = etu display time interval is adopted etu signal transmission data bit skew 0, 1 = etu + pdt display time ETU + PDT signal transmission data bit skewer adopting the interval.
In addition, for example, N =, and 2N length is set to N bit bits. Each skewer 00, 01, 10 and 11 is a new time parameter. Possible correspondence including bit bit skewer and time interval 00 = etu, 01 = etu + pdt, 10 = etu + 2pdt, 10 = etu + 3pdt, in which 00 = etu display is adopted ETU signal transmission data bit skew 00, 01 = etu + pdt display and time interval etu + pdt signal transmission data bit skew 01, 10 = etu + 2pdt display time interval etu + 2pdt Signal transmission data bit skewer, eleven = etu + 3pdt display, and time interval etu + 3pdt signal transmission data bit skewer. During this application, a combination of parameters that can be used in a time interval corresponding to a multi-format expression bit skew, not only that.
You can use the second device to send and receive new time parameters and to send data to the second device with new time parameters, for example, N = 0110 o'clock, sendable time interval etu + pdt data signal transmission 01, hair time interval etu + 2pdt data signal transmission. When new time parameter data is received by the second device, N = is taken as an example, when the reception time interval is a data signal of etu + pdt, the acquired data bit skew 01, the interval of reception time is the data of etu + 2pdt Acquire data bit skewer when signaled.
In the case of interrupted data transmission in this embodiment, the new time parameter new time parameter data is transmitted using the weekly frequency information transmission of the second device from the first device, and the frequency of information data transmission by the second device. Absorbing and / or sending and adjusting communication parameters during data transmission, improving communication efficiency.
What needs to be explained is that the time parameter for transmitting data is different from the acquired communication speed at the same time, and the purpose of the frequency of the adjustment parameter can be realized. For example, taking the current time is the parameter of the new time adjustment parameter (that is, taking the time to adjust the etu with the current time parameter, the new parameter of etu, taking the immediate time with the pdt parameter Adjustment is a new time parameter (pdt), and when performing data, it can be realized by changing the transmission frequency of transmission frequency, optimization of resource utilization, for example, it is not necessary when executing a specific application In order to reduce the communication speed and save the telecommunication speed achieved at this time, it is possible to increase the high communication speed ratio necessary for the execution of some applications, and at this time to realize the communication speed. Function to apply.

Example 6
In this embodiment, the frequency and information of the signal transmission handshake signal is a new time parameter, and the handshake signal is a new parameter generator at the first time. According to the flowchart of the genus transmission method of the present embodiment that provided an application showing FIG. 10, as shown in FIG. 10, this method mainly includes steps S1001 to S1005.
S1001, the new generation time handshake signal parameter is confirmed in the first device.
This embodiment implements a handshake signal for determining a new time parameter.
New time parameter determined in the signal for handshake signal generation and handshake time interval according to the number of methods, the number of first device definite generation handshake signals.
For example, a new handshake signal transmission time parameter for determining the number of deposits for the first device and the second device, and a handshake signal for the number of deposits generated by the first device. For example, the same handshake signal transmission new time parameter is used at the time interval of occurrence of the bee, and the new time parameter is adopted for the time interval signal of the handshake, and at which time interval in the specific handshake signal, the display etu and pdt The two devices are established as a communication partner, but this is not a limitation. For example, one of etu and pdt determines the relationship between the time interval in the same signal and the time interval in the same signal with etu, pdt, etu and pdt. In addition, the handshake signal of the generator according to the first time interval, and the new signal transmission time parameter that can be used for the one time interval when the handshake signal is generated according to the second time interval, and the time etu parameter, Pdt parameter during the new time in the second time interval.
Second, firstly a new system device time parameter determination first time interval set and / or a second time interval set; handshake signal of the first time interval set and / or second time interval set generated K.
In the handshake signal parameter including the new time, at least the group first time interval including one time interval, at least one second time interval including the second time interval set, the first time interval and the second time interval Satisfy the design relationship, the first time interval is the time interval between the start of the i-th handshake signal and the start time of the i-1th handshake signal, the second time interval is the i-th handshake signal Is the time interval between the beginning of i and the start time of the (i + 1) th handshake signal, i =, 4), 2j, j = (K-1) /, K is odd and K ,
For example, taking K = G as an example, the interval between the start of the handshake signal and the start of the first handshake signal in the definition of the eye is t0, and between the start of the definition handshake signal and the first handshake signal The interval between the start of t1 and the start time between the start of the second handshake signal and the start of the second handshake signal is t2, the definition of the start of the second handshake signal and the second The time interval between the start time between handshake signals is wine. The wine is the second time interval, the t1 pair including the second time interval, with the t0 pair including the first time interval and the t2 t1 including the first time interval, with the first t2 time interval along with the t0. Among them, the first time interval and the second time interval satisfying design relationship, for example, a constant multiple relationship, t 1 = 2 t 0 wine = 2 t 2. Of course, we do not limit here any other specific relationship that needs to be applied in practice and that also satisfies the first and second time intervals.
New parameters including any time, 2 hours parameter, first time parameter etu and second time pdt parameter, new time parameter fixed first time interval set and / or second time interval set realized below Under specific circumstances by taking the known etu and pdt in the street under a specific binary linear equation eg edu = t0, pdt = (t2-t0) / check t0 and / or t2 And satisfied with the design relationship in 1 hour interval and 2nd time interval t1 / or wine.
In addition, taking K = as an example, the interval between the start of the handshake signal and the start of the first handshake signal is t0 in the eye definition, and between the start of the handshake signal of the definition and the first handshake signal The interval between the start of t1, t0 is one hour interval, t1 second time interval. The new time parameter is a 2-hour parameter, the first time interval set and / or the second time interval set according to the first time parameter etu and the second time pdt parameter are as follows: Under the specific circumstances of known etu and pdt, edu = t0, pdt = t1. After that, along with the time interval t0 and t1's handshake signal generation.
S1002, First hand to second handshake signal transmitter.
S1003, second handset handshake transmitter receiving signal.
S1004, a new time parameter for the data transmission of confirmed frequency information by the second device.
Corresponding to the method of handshake signal generated in step 1001, the provision of this embodiment is also a new time parameter method of transmitting the frequency information fixed data by realizing the following two types.
A (new method and step 1001 middle), second device receiving handshake, new time parameter to determine the time interval between signal and handshake time interval in the signal.
For example, the second device shook the received signal and the handshake signal has the same interval, and this time interval is the new time parameter etu or pdt. One definite thing in etu and pdt in the relationship to meet etu and pdt. In addition, handshake the second device around the received signal, the same time interval between the previous handshake signal and the first handshake signal, and the same signal at the time interval between the previous handshake signal and the previous handshake signal. The second time interval establishes the first time interval and, as one of the new time parameters (etu and pdt), the second time interval is another new time parameter (etu and pdt). Exactly what the first device and the second device are negotiating and limit here anymore.
B (method and step 1001 corresponds to method 2), the second device is the first time interval set in the handshake signal and / or the second time interval set is the first time interval set and / or the second time interval set determination data New time parameter for transmission.
For example, taking K = go as an example, after a signal detection handshake, t0, t1, t2, wine in the handshake signal can be taken by taking the known t0, t1, t2, wine Under specific circumstances, certain binary linear equations, for example, edu = t0, pdt = (t2-t0) / check etu and pdt. This etu and pdt ie new time parameters of data transmission.
In addition, taking K = as an example, after the detection handshake signal, the interval between the handshake signal is edu, the second is the time interval t0 determination between the handshake signal and the first handshake signal. The time between t1's handshake signal and the second handshake signal t 1 constant the pdt interval is indeed not only the relationship between etu but also the above linear relationship to the pdt deposit, and other relationships are again limited do not do.
S1005, when supporting the second device for data transmission at a new time, according to the correspondence between each bit bit skewer and the time interval in the new time parameter new time parameter 2N length According to the correspondence relationship described above, the bit skewer corresponding to the time interval as acquired at the time interval in the transmission data signal or the data signal based on the new parameter reception data signal according to the time, of which the bit skewer is separate and different as 2N Unlike the time interval corresponding to the bit skewer, N is one.
For example, with N = N as an example, for N bit bits with a length of 2N, each skewer 00, 01, 10 and 11, a new time parameter and a new time parameter with 2N length in each of N Possible correspondence including bit bit skewer and time interval 00 = etu, 01 = etu + pdt, 10 = etu + 2pdt, 10 = etu + 3pdt, in which 00 = etu display is adopted ETU signal transmission data bit skew 00, 01 = etu + pdt display and time interval etu + pdt signal transmission data bit skew 01, 10 = etu + 2pdt display time interval etu + 2pdt Signal transmission data bit skewer, eleven = etu + 3pdt display, and time interval etu + 3pdt signal transmission data bit skewer.
The second device can be used to send and receive new time parameter data, and to send data to the new device to the new time parameter, for example, N = and the required data bit serial 0110 For transmission, the time interval (etu + pdt) transmission data signal transmission bit skew 01, and the time interval (etu + 2pdt) transmission data signal transmission bit skewer. When new time parameter data is received by this second device, for example, N =, the time interval to the received data signal is etu + pdt, the acquired data bit skew 01, the time interval to the received data signal is etu + 2pdt When you get the data bit skewer.
In this step, the second device is informed of the weekly frequency confirmation information as the device transmission data signal and transmission data signal for the first time in the correspondence between each bit bit skewer and the time interval in the length N with the new time 2N parameter The device adopts the number according to the number of parameters to adjust the time transmission to obtain new time parameters and the corresponding communication speed with the new time parameters.

In this example, when a handshake signal is generated, it can be realized by generating a low-level pulse. Or it cannot be realized by other waveform signals. There is no limit here.
Then, in this embodiment, for the first time in step 1001, the apparatus acquires a new parameter in time with the handshake signal of the generated K and the first apparatus sets the length of 2N to each bit bit skewer and the time interval of N. Sending data signal by correspondence by correspondence. The numerical value of this data signal is transmitted by the first device, the data of the second device, even if there is no possible time to include this data, the new parameter is the parameter including the new time, the method of the first device transmitted data signal and the second Just like the device transmit data signal, here is a luxury. At this time, in step 1005, the second device skews the time interval acquisition time interval corresponding bits in the data signal based on the new time parameter data reception signal.

In this embodiment, under the situation of interrupted data transmission, for the first time handshake and signal device, the second device's frequency information transmission, new time parameter using the second device's weekly frequency information data transmission By absorbing and / or sending data, communication parameters were adjusted for data transmission and communication efficiency was improved.

Example 7
In this embodiment, the frequency of the week and the information are the new time parameter data transmission signal, this data signal, firstly the current time parameter generator. According to the flowchart of the genus transmission method of the present embodiment that provided the application shown in FIG. 11, the data transmission method of the present embodiment is mainly steps S1101 to S1105 as shown in FIG.
S1101, F data signal for which the current time of data transmission by the first device is a parameter for the time being and the length of 2N parameter time is N, and the corresponding relationship occurs according to the correspondence between each bit bit skewer and the time interval The time interval at the beginning of all data signals and the start of one signal adjacent to each other is the time interval corresponding to the bit skew, F is a natural number, F is a new data signal transmission time parameter.
Among them, it can be used for data signal to transmit data. In this embodiment, F data signals are adopted and a new time parameter is transmitted.
The current time parameter is a time parameter adopted by the first device and the second device during data transfer. Optional two-hour parameters, including the current parameter at the time, the first time, the parameter etu and the second time pdt parameter.
In this step, the time is set for the first time in the device. For the time being, the current time parameter is set to the length of 2N and the correspondence between each bit bit skewer and the time interval in N. Similar to the realization of the interval correspondence between each bit bit skewer time in N and the length of the new parameter under 2N parameter, here is another luxury.
Depending on the sample property, the current time of data transmission at this step is the current parameter and the length of the 2N parameter time is the corresponding relationship described by the corresponding relationship between the bit bit skewer and the time interval in N F Realization of the data signal is as follows: Newly adopted data bit serial 00101101 time parameter, for example, N, when this, 2N length, N bit bits, each skewer 00, 01, 10、11 、 temporary time 2N parameter length includes the correspondence between each bit bit skewer and time interval in N 00 = etu, 01 = etu + pdt, 10 = etu + 2pdt, 11 = etu + 3pdt, in which 00 = etu display is adopted and the time interval is etu signal transmission data bit skew 00, 01 = etu + pdt display is adopted and the time interval is etu + pdt Transmission data bit skew 01, 10 = etu + 2pdt Adopt display time interval etu + 2 pdt signal transmission data bit skewer, eleven = etu + 3pdt display and time interval etu + 3pdt signal transmission data bit skewer.
The transmission data bit serial 00001011 (new time parameter) includes the transmission data bit skew 00, two for the code generation signal F to be performed, and the interval between the first signal and the second signal for etu. The interval between the third and third signals for etu + 2pdt, the transmission data bit skew, the interval between the third signal and the fourth signal for etu + 2pdt, the transmission data bits Kushijyu, the transmission data bit skewer for the etu + 3pdt interval between the fourth and fifth signals.
S1102, 2nd F data signal transmitter from first device.
For example, the first device can transmit F data signals in the following manner:
Get the serial number of the data bit that displays the new time parameter,
Group data bit serial, one bit N bit data bit,
The same group data bit skewer that can display the same data bit skewer at the time interval corresponding to each paired data bit skewer according to the correspondence of acquisition.
S1103, F transmission device reception data signal of the second first device.
S1104, a new time parameter for the time interval between the start time of each data signal into the F data signal according to the F parameter that receives the time data signal according to the second device.
The newly adopted data bit serial 00101011 time parameter of the sample property is taken as an example when N is set to N. At this time, it can be known at step 1101 that F = If the detection time interval is etu is 00, the decoded data bit skew is 00, if the detection time interval is etu + 2pdt, the decoding data transmission is the same bit skew, if the detection time interval is etu + The data transmission of 3pdt decoding can get the data bit order 00101011, thereby obtaining the new time parameter, which will sequentially decode before and after the reception time.
S1105, when supporting the second device for data transmission at a new time, according to the correspondence between each bit bit skewer and the time interval in the length of 2N in the new time parameter new time parameter According to the correspondence relationship described above, the bit skewer corresponding to the time interval as acquired at the time interval in the transmission data signal or the data signal based on the new parameter reception data signal according to the time, of which the bit skewer is separate and different as 2N Unlike the time interval corresponding to the bit skewer, N is one.
Step S1105 is specifically realized and referred to in connection with the example Roku S1005 and is now a luxury.
In this step, the second device is informed of the weekly frequency confirmation information as the device transmission data signal and transmission data signal for the first time in the correspondence between each bit bit skewer and the time interval in the length N with the new time 2N parameter The device adopts the number according to the number of parameters to adjust the time transmission to obtain new time parameters and the corresponding communication speed with the new time parameters.
Of course, this embodiment includes the following steps: Supporting the second device for data transmission of parameters at a new time, the current 2N parameter length at each bit bit skewer in N at that time The frequency of the data signal of the shipping confirmation information that shows the table on the device for the first time in the correspondence between skewers and time intervals. That is, the second device informs the current shipping time of the parameter confirmation information of the frequency of the parameter. Adopts the first device The parameter adjustment data transmission time is obtained with the new time parameter and the new time-compatible communication speed parameter, which is the later data transmission Data transmission time parameter newly towards the.
What needs to be explained is optional, this embodiment is the first time in step 1101 with the data signal of the current time parameter generation F to the device (new time parameter for F data signal transmission), the first device is now with 2N parameters Second other data signal transmission device in correspondence with the interval of time length from each bit skewer to the utter time in N. The other data signal transmission device first transmits the other data of the second device, the first device generated transmission of the other data signal system, the transmission to step 1101 is the same as the F data signal, It's a luxury here. Alternatively, before the parameter generation F data signal (new time parameter for F data signal transmission) at the current time on the first device, the first device sends the handshake signal at the parameter generation time for the time being.

In this embodiment, under the situation of interrupted data transmission, for the first time, the device uses the second device to transmit the frequency information of the second device to the data signal, the new device uses the frequency of the information data transmission by the second device, the new time parameter By absorbing and / or sending data, communication parameters were adjusted for data transmission and communication efficiency was improved.

Example 8
Distinguishing between the present embodiment and the embodiment: the frequency information is a new time parameter indicator, the other implementation is the same as the embodiment process, the same content is not detailed, please refer to the description about the embodiment.
In this embodiment, the frequency information also includes the data transmission signal, this data signal, and firstly the current time parameter generator. According to the flowchart of the one-type transmission method even if the application of this embodiment is provided as shown in the figure, the data transmission method of this embodiment is mainly from step 1201 to step 1205 as shown in FIG.
According to S1201, the current time of data transmission is a parameter for the time being, and the length of 2N parameter time is a data signal of F that generates a correspondence according to the correspondence between each bit bit skewer and time interval in N, Among them, the time interval at the start of one signal that is adjacent to the beginning of all data signals is a time interval corresponding to one bit skew, F is one and F is a natural number, F data signal is a new time parameter display .
In this embodiment, the F data signal transmission time parameter new indicator, the new time parameter indicator is the frequency information.
S1202, 2nd F data signal transmitter from first device.
For example, the first device can transmit F data signals in the following manner:
Get the serial number of the data bit that displays the new time parameter,
Group data bit serial, one bit N bit data bit,
The same group data bit skewer that can display the same data bit skewer at the time interval corresponding to each paired data bit skewer according to the correspondence of acquisition.
S1203, F transmitter reception data signal of the second first device.
S1204, receive the time data signal according to the second device F time by the F parameter to the F data signal new time parameter indicator between the start of each data signal, new time parameter corresponding to the new parameter indicator in the default search time table.
In this, the display of the new time parameter corresponds to the new time parameter one by one. For example, the new time parameter corresponding to the new time parameter indicator 0 is etu = 100 us, pdt = 10 us, the new time parameter indicator is temporary, the corresponding new time parameter is etu = 10 us, pdt = 1 us, and so on. A new time parameter that determines the new time parameter indicator by examining the table through the correspondence between the new time parameter indicator containing the default table and the new time parameter.
S1205, when supporting the second device for data transmission at a new time, according to the correspondence between each bit bit skewer and the time interval in 2N length in the new time parameter new time parameter According to the correspondence relationship described above, the bit skewer corresponding to the time interval as acquired at the time interval in the transmission data signal or the data signal based on the new parameter reception data signal according to the time, of which the bit skewer is separate and different as 2N Unlike the time interval corresponding to the bit skewer, N is one.
In this step, the second device is informed of the weekly frequency confirmation information as the device transmission data signal and transmission data signal for the first time in the correspondence between each bit bit skewer and the time interval in the length N with the new time 2N parameter The device adopts the number according to the number of parameters to adjust the time transmission to obtain new time parameters and the corresponding communication speed with the new time parameters.
Of course, this embodiment includes the following steps: Supporting the second device for data transmission of parameters at a new time, the current 2N parameter length at each bit bit skewer in N at that time The frequency of the data signal of the shipping confirmation information that shows the table on the device for the first time in the correspondence between skewers and time intervals. That is, the second device informs the current shipping time of the parameter confirmation information of the frequency of the parameter. Adopts the first device The parameter adjustment data transmission time is obtained with the new time parameter and the new time-compatible communication speed parameter, which is the later data transmission Data transmission time parameter newly towards the.
What needs to be explained is optional, this embodiment is the first device in step 1201 with the current time parameter generation F data signal (new time parameter indicator on the F data transmission signal) for the first time, and the first device now has 2N parameters According to the second other data signal transmission device to the correspondence of the interval between each bit bit skewer time in the length of time N. The other data signal transmission device first transmits the other data of the second device, the first device generated transmission of the other data signal system, the transmission in step 1201 is the same as the direction of the F data signal, It's a luxury here. Alternatively, before the parameter generation F data signal (new time parameter indicator for F data signal transmission) at the current time on the first device, the first device is the second device that sends a handshake signal at the parameter generation time for the time being.

In this embodiment, under the situation of interrupted data transmission, for the first time, the device uses the second device to transmit the frequency information of the second device to the data signal, the new device uses the frequency of the information data transmission by the second device, the new time parameter By absorbing and / or sending data, communication parameters were adjusted for data transmission and communication efficiency was improved.

It is necessary to explain that, in the embodiment from the above embodiment, in the embodiment, after the second device acquisition new time parameter, it is determined whether to support the second device including the above method. The following two implementations can be employed:
Determine whether the second time is within the range of the data transmission time parameter supported by the new device parameter itself. If the new time parameter to be determined is within the range of the data transmission time support parameter of the own device, the second device confirms the new support parameter. Data transmission with time parameters.
Sampled, stored in the second device The range of data transmission time parameter supported by itself is, for example, edu range is 1us-100us, pdt range is 0.1us-10us, second device new time parameter is determined after each new time parameter In edu, within edu, within pdt, within pdt, edu and pdt are all within their respective ranges, and the explanation is data on new support time parameters in the second device transmission. Otherwise, for example, edu and pdt are present within the corresponding range, and the explanation of data transmission at a time that does not support the second device.
If the second device looks for whether there is a search in its supporting data transmission time parameter table, the new device will transmit the new time parameter, the new device will support the new time parameter.
Sampleability, stored in a second device, self-supported data transmission time parameter list, eg see table below:

After the second device new time parameter, find out whether it is included in the table with new time parameter edu and pdt. If the search and explanation are data transmission of a new support time parameter to the second device, for example, when the new time is edu = all parameters us, pdt = us, the time that can be searched in the above table is the time parameter of the parameter indicator. The same explanation parameters for the new time are edu = 50us, pdt = 5us data transmission by the second device. Otherwise, explain that the second device does not support performing data transfer with new time parameters.
Of course, as an option, whether the frequency information is present in the data transmission time parameter table supported by the second device, whether it is in the new transmission time parameter indicator, the new search time parameter indicator, if the new search time parameter indicator, Supports new data transmission through the equipment.

Example 9
This application example is also provided according to the number of types, and for the transmission system, the above data transmission execution method, the function of this system is realized, the description about the strawberries reference from the above example, with the same or similar flow It's already a luxury. The first device and second device of this system are mainly from devices. As an apparatus of a main facility, for example, a terminal, for example, an apparatus from the facility is an electronic payment facility (for example, an electronic signature tool key, a smart card, a key card uniting facility, etc.).
The following briefly describes the system:
As shown in the figure, the system includes: the first device and the second device, in which the first device, to obtain information, the frequency, and secondly, the frequency information of the transmitting device; the second device, receiving According to the transmission information for the first time in the device's frequency, the new frequency parameter for deterministic data transmission of the frequency information is supported; when the data is transmitted according to the new time, the new time parameter is set to 2N length in N Each bit bit skewer and time interval corresponding bit as described in the correspondence relationship described as a transmission data signal, or a new data reception signal parameter on time according to the data as the time interval in the signal is acquired The skewer, of which the bit skewer is separate, like 2N, and is different from the time interval corresponding to the bit skewer.
Sampled, first device is handshake and signal transmission weekly frequency information, weekly frequency information is a new time parameter; at this time, the first device, specifically a new parameter at the time, the first time interval set and / or the second time Set according to the interval; the first time interval set and / or the second time interval set generated K handshake signal including new time, handshake signal parameter, at least one group first time interval including one time interval, At least one second time interval, including two time interval pairs, full foot design relationship between the first time interval and the second time interval, the first time interval between the beginning of the i-th handshake signal and the i-1 The time interval between the start times of the handshake signals, the second time interval i between the start of the i th handshake signal and the start time of the i + 1 handshake signal, i = 2, 4, ……, 2j, j = (K-1) /, K is odd and K.
The second device, to obtain the first time interval set and / or the second time interval set in K's handshake signal; the first time interval set and / or the second time interval set the new time of the confirmed data transmission Parameter.
Sample signal, the first device is the data signal transmission frequency information, the frequency information is the new time parameter; at this time, the current time of data transmission by the first device is specifically set as the parameter for the time of 2N parameter time According to the correspondence between each bit bit skewer and the time interval in N, the F data signal that has a corresponding relationship, of which the time interval at the start of one signal is adjacent to the beginning of all the data signals Bit skewer corresponding time interval, F is a natural number, F is a natural number, F data transmission time letter No. New parameter; second device, specifically receiving parameter data signal according to time F to F data signal each data New time parameter for the time interval between the start of the signal.
Sampled, the first device is the data signal transmission frequency information, the frequency information is a new time parameter indicator; this second device, specifically the current time of transmission according to the data is a parameter for the time being 2N parameter time length N According to the correspondence between each bit bit skewer and the time interval, the F data signal that has a correspondence relationship, of which the time interval at the start of one signal is adjacent to the beginning of all the data signals At the time interval corresponding to the skewer, F is a natural number, F is a natural number, F is a new data signal transmission time parameter indicator; the second device, specifically receiving the parameter data signal according to the time F to the F data signal Time interval new time parameter indicator, new time parameter corresponding to the new parameter indicator in the default search timetable.
In addition, the number of weeks to inform whether the device can be performed for the first time, the use of the second device, by data transmission support new time parameter, the current 2N parameter length in N The number of weeks in the data signal of the shipping confirmation information to indicate the device for the first time in the correspondence between each bit bit skewer and the time interval.
The ability of data transmission to make its own support new time parameter to determine whether the sampled, second device pending to provide the system of this embodiment can also be realized:
The second device determines whether the time is newly determined within the range of the data transmission time parameter supported by itself, and if the new time parameter to be determined is within the range of its own data transmission time support parameter, the second device confirms the new support Whether the time parameter is data transmission;
If the second device, look for whether there is a search in its supported data transmission time parameter table, the new time parameter, the new time parameter, the new time parameter to the confirmed second device support data transmission.
In the system provided by the present embodiment, under the situation of interrupted data transmission, for the first time, the device transmits a new time to the data signal by using the second device's frequency information and the second device's information data transmission frequency. Parameter new time Parameter absorption and / or sending of data, adjustment of communication parameters during data transmission, communication with improved efficiency.

Example 10
The method of receiving and using the method of the first embodiment is a signal receiving side (for example, the receiving side or the data receiving device in each of the above embodiments), filtering the received signal, and an effective signal.
As shown in FIG. 14, the method mainly includes the following steps (steps S1402 to S1410) as shown in the flowchart of the receiving method provided by the present embodiment.
Step S1402 is the correspondence between each bit bit skewer and the time interval in the length of 2N in N. Among them, N is different from the time interval corresponding to 2N bit skewer separately and different bit skewer. .
In this embodiment, the length is a time interval that can correspond to N bit skewers, and is not the same in time intervals corresponding to different bit skewers as long as it can cope with many time intervals.
In the optional implementation method of the present embodiment, the current data transmission time parameter is the correspondence between each bit bit skewer and the time interval in 2N length N. In some cases, the current data transmission time parameter is discussed in advance with the sending side, or the data sent from the sending side, for example, the sending side sends the handshake signal, handshake and signal first before sending data. The data transmission time parameter for the time being transmitted to the receiving side, a specific example not specifically limited. Therefore, in the option implementation method of this embodiment, the determinable time parameter is set before the above correspondence. For example, if there are two time edu and pdt parameters, the time interval corresponding to each bit skew in the length is as shown in the table. Of course, the present invention is not limited to this, and in fact, it is possible to adopt the correspondence between the time interval and the parameter corresponding to each bit skew, and the other relations described in detail in the table are already a luxury.

Of course, not limited to this, in another option implementation method of the present embodiment, the parameter is not based on the above-described correspondence relationship depending on the time that cannot be performed, but a preset rule (for example, the above table 1) or the above-described correspondence relationship directly. For example, if N = 1, the time interval corresponding to the directly promised bit 0 and bit 1 is, for example, 10 μs and 15 μs, respectively. Alternatively, the above correspondence can be received, and the present embodiment is not specifically limited.
In the case of the above correspondence relationship with the parameters according to the time, N = n, the transmission data bit m as in the calculation method of data reception side adoption and data transmission side prior consultation determination and the time interval of data bit calculation The time interval TM = etu + m * pdt (0 m ≦≦ 2n−1) is also a calculation method determination time interval that can adopt another prior consultation, and is not specifically limited in this embodiment. This data bit time interval, which is calculated through prior consultation, is the scalability of the transmission of guaranteed data, that is, no matter how N, the sending data side and the receiving side are the time intervals of the calculation data bits.
In step S1404, the received Y + 1 signal, the first signal in the Y + 1 signal is Y, and the signal for starting the data transmission for instruction is Y, and Y is a positive integer, Y + 1 Total number of received signals.
In this embodiment, an instruction and a signal to start data transmission are the first data signal of data transmission, for example, the first data signal after reception of the scheduled time (same time, reception side and transmission side commitment confirmation) Or the handshake signal sent to the receiving side before sending data to the receiving end is the last signal in the handshake signal from the receiving and sending side as well as an instruction to start data transmission. In this embodiment, the handshake signal is transmitted to the transmission side at the start time of the instruction data transmission / reception side.
For example, the handshake signal parameters of the transmission side on the transmitting side, including time 2: handshaking etu and pdt, and at the time interval of the signal: t0, t1 t2, respectively, wine t0 = etu, t1 = etu + pdt can be determined according to the receiving side, t0 t 1 time etu and parameter pdt, or t 2 and wine in the second time interval set are also determined, 2t2 = 2etu, 2t1 = (Etu + pdt), according to the receiver side wine can also be confirmed t 2 hours etu and pdt parameter. Alternatively, the pdt parameter in terms of time etu can obtain t0 and t1 as long as through other relationships that t0 and t1 can also satisfy. Also, if there is only one time parameter directly and this time parameter is determined by one time interval in the K handshake signal, or if the three parameters are the time interval between signals through the K handshake The specific example of the three-hour parameter determined by the satisfaction relationship is already a luxury. If the time to overcome the handshake parameter through the K signal, the receiving side theory and the actual time parameter do not match, the data transmission accuracy is guaranteed.
Instructed in step S1406, the signal for starting data transmission is confirmed as the first valid signal.
S1408 Judgment procedure, when starting the reception Z signal, if the time interval at the start of the previous valid signal is to be obtained, if one time interval in the corresponding relationship, whether the Z signal is valid , Of which Z =, san, yoshiyo ... Y + 1.
Sequentially receives the judgment in step S1408 Z (Z =, san, 4, yo + 1), at the start of the signal, whether to obtain the time interval at the start of the previous valid signal The corresponding request signal record cannot be discarded effectively until the judgment up to the Y + 1th signal at the recording time interval, and the corresponding request signal efficiently filtered noise signal, guarantee Accuracy and completeness of data transmission.
For example, the transmission time parameter is now a 2-hour parameter, that is, the first time parameter etu and the second time parameter pdt, where etu = 10 μs, pdt = 10 μs. N = time of time, time parameter corresponding to bit skew (that is, 1-bit data or first-order bit skew), that is, a time interval corresponding to 0, etu, and a time interval corresponding to pdt, pdt. After receiving the valid signal for the first time after receiving the receiver's confirmation, sequentially determine the Y signal of the turn and calculate the signal at the start of the same signal to receive, the time interval at the beginning of the first valid signal license is 10 μs, Since the same time interval and the time interval corresponding to the first bit skew 0 are not the same, the signal is a valid signal, and the signal D for invalidating the signal recording is discarded.
The time interval at the start of the decision signal for the first time and the valid signal C 1 for the first time is 20 μs, and the same time interval and the same time interval corresponding to the first bit skewer, so the signal is the valid signal Record the second valid signal C 2 and at the start of the second valid signal C 2.
Time interval between the start time of the 4th determination signal and the start time of the second valid signal C2 ... For this reason, until the Y + 1th determination signal ends until reception.
In the optional implementation plan of this application example, when the Z-th signal starts, the time interval at the start of the previous signal is larger than the default value. That is, in this option implementation plan, after the completion of the valid signal for the first time in step S1404, the initial signal at the start time of the hardware layer filtering drop-off signal on the receiving side and the time interval at the start of the previous signal is the default signal. Even in response to the receiving MCU unpleasant signal, only at the start of the current signal, the time interval at the start of the previous signal can increase the current signal of the equal default value (ie the Zth signal). In response, reducing the subsequent effective signal detection efficiency, less MCU workload.
In addition, the following hardware layer filter can be adopted: The first valid signal received from the receiver side to the receiver T from the start of the chronograph, within T + default value range The time at which no signal is received, T + default value from this moment to the received signal from the heavy Z to the received signal Z (Z =), the start time of the Z signal (Z = to) and the new T Until the Y + 1th received signal, repeat the above procedure.
Further, the minimum value of the time interval in the correspondence as described above in step S1402 acquisition of the above default value. The time interval from the start of the current signal to the start time of the previous signal is the minimum value of the time interval in the corresponding relationship.
In the optional implementation method of the present embodiment, the received Y + 1 signal is detected, and the Y + 1 degree low level pulse is detected and the level pulse detected is Y + 1 degree higher. The waveform display of high and low level pulses can be divided into square wave, positive wave, triangular wave, etc. that can adopt the same low level pulse / high level pulse, but this is not limited. In step S1410, a determination result is obtained, and an X valid signal, where X ≦ Y + 1, and X is a positive integer.
Based on the determination in step S1408, decoding is performed with the X effective signal based on the effective signal of X, and the transmission side data is transmitted. Therefore, in the optional implementation plan of the application of this embodiment, even after step S1410, S1412-step S1416 including the following procedure (not shown in the figure).
Step S1412, the time interval between the times adjacent to the beginning of the two signals for each valid X valid signal, get X-1 time interval.
In step S1414, the correspondence relationship acquired in step S1414 is obtained as a bit skewer corresponding to one hour interval at each successive S time interval at X-1 time intervals, and transmitted at S time interval bit skewer, of which S time interval transmission. If the bit skewer is a bit skewer corresponding to one time interval, S>, the time interval of S is the same, S is a positive integer, and S X−1 ≦.
In the option implementation method of the present embodiment, X-1 = n * S, where n is an integer and n is an integer, and this option implementation method, X signal transmission n * S is not a data bit that can be the same, There is no decoding problem due to extra signals.
For example, I X =, S = 1 o'clock, I am a time interval, and the corresponding time interval is a bit skewer; X is over and above, S = 1 is acquired at many time intervals, each time Interval-compatible bit skewer: When X = san and S =, the two time intervals are the same in two time intervals, and the two time intervals correspond to the same time interval. Bit skews; X, such as S, is set to 4 time intervals, more than one time interval corresponding to the previous two consecutive time intervals, more than two consecutive time intervals. One bit interval corresponds to another bit skewer, ie up to 2 hour interval is bit skewer, after 2 hour interval is another bit skewer. Of course, with the above example, all of the bit skewer methods of sampled, time-sequential transmission of S as much as possible should belong to the protection scope of this application.
In step S1416, the bit serial transmission of the X-1 time interval is obtained by switching the bit skew of the time interval transmission of each continuous S at the X-1 time interval.
For example, if X = 10, S, S = 1, and the time interval obtained in step S1414, “01”, “00”, “01”, “10”, “10” ”,“ 10 ”,“ 00 ”and“ 01 ”are the last obtained bit serial of the time interval transmission“ 0100011011100001 ”.
Arbitrarily, the obtained X-1 time-interval transmission bit serial data is decoded, and the obtained X-1 time-interval transmission data is decoded to the bit group composition byte at the interdigit, resulting in X-1 time Interval data transmission.
In the optional implementation plan of this application example, the check bit including the bit serial of X-1 time interval transmission, for example, the last byte is in the check position, and the data integrity check before the check bit is further in the same check position. Including, but not limited to, data integrity checking, CRC odd / even checking, digital signatures, taking and checking, MAC checking, etc.
Arbitrarily, after the Y + 1 signal, A is a signal (A is an integer) from the transmitting / receiving end, or A is a signal in Y + 1 including the signal. The handshake signal, which is the same as the end signal, is transmitted through signals of other specific formats.
Through the provision of this embodiment, the reception method, effective filtering noise, and reception efficiency are enhanced.

Example 11
FIG. 15 is a flowchart of a receiving method provided by this embodiment. FIG. The difference between the method provided in the present embodiment and the method provided in the first embodiment is that, in the embodiment, the receiver sequentially determines whether each signal is valid from the Y + 1 signal received, the first valid signal in the present embodiment. After confirmation, all received signals are immediately judged as to whether this signal is valid. Compared to Example 10, the efficiency of the method provided in this example is even higher.
As shown in the figure, the receiving method provided by the present embodiment mainly includes the following procedures (step S1502 to step S1508).
Step S1502 corresponds to the relationship between each bit bit skewer and the time interval in the length of 2N in N. Among them, the bit skewer is separate as in 2N, and differently from the time interval corresponding to the bit skewer, N is one.
In this embodiment, the length is a time interval that can correspond to N bit skewers, and is not the same in time intervals corresponding to different bit skewers as long as it can cope with many time intervals.
In the optional implementation method of the present embodiment, the current data transmission time parameter is the correspondence between each bit bit skewer and the time interval in 2N length N. In some cases, the current data transmission time parameter is discussed in advance with the sending side, or the data sent from the sending side, for example, the sending side sends the handshake signal, handshake and signal first before sending data. The data transmission time parameter for the time being transmitted to the receiving side, a specific example not specifically limited. Therefore, in the option implementation method of this embodiment, the determinable time parameter is set before the above correspondence.
Of course, the present invention is not limited to this, and in another option implementation method of the present embodiment, the parameter is not set in the above-mentioned correspondence relationship depending on the time that cannot be obtained, and a rule set in advance is obtained. In the case of 1 = 1 hour interval corresponding to itter 0 and bit from direct promise, for example, 10 μs and 15 μs, respectively. Alternatively, the above correspondence can be received, and the present embodiment is not specifically limited.
In the case of the above correspondence relationship with the parameters according to the time, N = n, the transmission data bit m as in the calculation method of data reception side adoption and data transmission side prior consultation determination and the time interval of data bit calculation The time interval TM = etu + m * pdt (0 m ≦≦ 2n−1) is also a calculation method determination time interval that can adopt another prior consultation, and is not specifically limited in this embodiment. This data bit time interval, which is calculated through prior consultation, is the scalability of the transmission of guaranteed data, that is, no matter how N, the sending data side and the receiving side are the time intervals of the calculation data bits.
In step S1504, the signal is the first valid signal as a cue to start transmitting instruction data to the reception.
In this embodiment, the instruction data transmission start signal is the first data signal for data transmission, for example, the first data signal after receiving the scheduled time (same time, reception side and transmission side commitment confirmation), or The handshake signal is sent to the receiving side before the data is sent from the receiving side to the transmitting side, the signal is the last signal in the handshake signal from the receiving and sending side as well. In this embodiment, the handshake signal is transmitted to the transmission side at the start time of the instruction data transmission / reception side.
Step S1506, at the start of the Z-th signal to continue receiving and judging, at one time interval in the correspondence as to whether to obtain the time interval at the start of the previous valid signal, if the Z-th signal Record the signal effectively, of which Z = 1, 2, 3, 4, Y, Y, Y is the number of signals that continue to be received, Y is a positive integer,
At the start of the reception Z signal through sequential determination, the corresponding request will not be processed until the determination at the Y time signal is completed at the recording time interval at the time interval at the start of the previous valid signal at the time interval of recording. The signal that is recorded and not discarded is effective, the signal of the corresponding request is effectively filtered, the noise signal of the dropped channel, the accuracy and completeness of the transmission of guarantee data.
For example, the first transmission time parameter etu and the second transmission time parameter pdt, where etu = 10μs, pdt = 5μs are used as an example for the time of transmission time parameter, and the time is different during step S1502. The parameters are shown in the table at time intervals corresponding to data bits.

For the received data transmission, after the first valid signal license of the instruction start signal, after 10 μs, the received first signal is the same time interval as the start time of the first signal and the time interval when the valid signal starts for the first time And since the same time interval corresponding to the skew according to Table 2:00, the signal is recorded effectively, the signal is the second valid signal C2, and at the start of that second valid signal C2.
The signal continues to be calculated, the time interval between the start time of the same signal and the start time of the second valid signal C 2 is about μs, the same time interval and the table 2 bit skew 00, 01, 10 and 11 Because the time interval corresponding to is not the same, the signal D to invalidate the signal recording that effectively validates the signal throws away the invalid signal D.
For the reception Z signal (Z = san), until the start time when the signal needs to be calculated and the start time of the second valid signal C2, until the reception Y signal ends. The last available signal (C1-C6).
In the optional implementation method of the present embodiment, the Y signal that has been continuously received for the first time after reception is detected and the Y + 1 degree low level pulse is detected, and the Y + 1 degree higher level pulse is detected. The waveform display of high and low level pulses can be divided into square wave, positive wave, triangular wave, etc. that can adopt the same low level pulse / high level pulse, but this is not limited. Provides a low level pulse that detects the preferred, ie, the receiving side at the transmitting side, and under high level conditions, the low level pulse, this scheme allows the receiving side to be used when communicating with the receiving side transmitting side As a high-level power supply provided on the transmission side, electrical components that provide power consumption on the reception side, for example, equipment of a high-level charging method provided on the transmission side that can be used by the reception side is adopted, and a single line of information is alternately displayed. As soon as it is used, the completed power supply and information are received.
In step S1508, after obtaining the determination result based on the received Y signal, the X valid signal, X ≦ Y + 1, and X is a positive integer.
In the process of step S1506, decoding of the X effective signal and follow-up, the reception complete Y signal is used for decoding with the X effective signal, and the result is transmitted on the transmission side.
Through the provision of the above-described method through the provision of this embodiment, after a signal of the start of transmission of received data, the signal recording is valid every time a signal is received, the subsequent signal is the interval between this signal and the previous valid signal If the time interval corresponding to an arbitrary bit skew is N, and the signal is ignored, the time interval corresponds to one bit skewer of the length of N. The time interval enables this signal recording through the signal, this method effectively increases the letter and noise interference signal, the accuracy and stability of data transmission.
In the optional implementation plan of this application example, after step S1508, the X serial signal is further effectively decoded and the X serial signal is transmitted as a bit serial. Therefore, after step S1508, possible steps S1510 to S1514 including the same method (not shown in the figure).
In step S1510, the time interval between the beginning times of every two signals adjacent to the definite X valid signal, get X-1 time interval.
In step S1512, the correspondence relationship acquired in X-1 time interval is obtained for each successive S time interval, and a bit skewer corresponding to 1 hour interval is obtained, and in this time interval transmission bit skewer, the same S time interval The transmission bit skewer is the first bit skewer corresponding to the above-mentioned one hour. Under the circumstances of S> 1, the time interval of S is the same, S is a positive integer, and S X−1 ≦.
In the option implementation method of the present embodiment, X-1 = n * S, where n is an integer and n is an integer, and this option implementation method, X signal transmission n * S is not a data bit that can be the same, There is no decoding problem due to extra signals.
Step S1514, bit serial transmission of X-1 time intervals obtained by splicing the bit skew of each continuous S time interval transmission at X-1 time intervals.
For example, if X = 10, S, S = 1, the time interval obtained in step S1510, “01”, “00”, “01”, “10”, “10” ”,“ 10 ”,“ 00 ”and“ 01 ”are the last obtained bit serial of the time interval transmission“ 0100011011100001 ”.
In the optional implementation plan of this application example, after step S1514, further decoding is performed with the bit serial obtained, and the bit serial of the X-1 time interval transmission is obtained. As a result, X-1 transmission data at intervals.
In addition, check bits including the bit serial of X-1 time interval transmission, for example, checking the integrity of the data before the check bit at the check position with the last byte as the check position. Including, but not limited to, data integrity checking, CRC odd / even checking, digital signatures, taking and checking, MAC checking, etc.
In the optional implementation method of this embodiment, when the reception Z signal starts, the time interval at the start of the previous signal is larger than the default value. Optional Step S1504 Completion Reception After the first valid signal, the reception side hardware layer filtering drop signal for the time being and the time interval between the start time of the previous signal is the default value for the immediate signal, the receiving MCU or this signal At the beginning of the current signal, the time interval at the start of the previous signal responds by raising the current signal of the equal default value (ie the Zth signal) and the subsequent effective signal detection efficiency. Reduced MCU workload.
In addition, the following hardware layer filter can be adopted: The first valid signal received from the receiver side to the receiver T from the start of the chronograph, within T + default value range In the time when no signal is received, T + default value From this moment, the new Z to Z (Z = 1) from the heavy new signal to the received signal received signal, the start time of the Z signal (Z = 1) and the new T Repeat the above procedure until the Yth signal is received.
In addition, the above set value can be the minimum value of the time interval recorded in the acquired correspondence. S1506 that does not belong to the current signal because the minimum value of the time interval in the corresponding relationship from the start of the current signal is the same as the time interval at the start of the previous signal. To this current signal.
In the option implementation plan of this application example, A from the transmission side is continuously included in the received Y signal (A is an integer), or it is sent from the transmitting / receiving end after receiving the Y signal. A is a signal. The handshake signal, which is the same as the end signal, is transmitted through signals of other specific formats.

Example 12
One type of receiving device that provides this embodiment, the receiving method described in the execution embodiment in the device, the data in the receiving device according to the embodiment, the receiving device, that is, the receiving device described in this embodiment The function of the receiver in the embodiment as a function is added.
In this embodiment, the receiving device is an electronic payment facility that functions as a smart card and / or an intelligent key facility and / or a dynamic password tag.
FIG. 16 is a guide diagram of the structure of one type of receiving device provided by this embodiment. As shown in FIG. 16, this device mainly includes: time unit 120, absorption unit 110, recording unit 140, judgment unit 130. And valid signal acquisition unit 150. Next, a description will be given.
In order to obtain a unit of time interval, the length of 120, 2N is the correspondence between each bit bit skewer and the time interval in N, among which the time corresponding to 2N bit skewer separately and different bit skewer Unlike the interval, N is one.
In the optional implementation method of the present embodiment, the time parameter is set to the unit 120 or less through the time interval in accordance with the above correspondence relationship: the data transmission time parameter for the time being, and the time parameter is set to 2N length in each bit in N Correspondence between bit skewers and time intervals. In some cases, the current data transmission time parameter is discussed in advance with the sending side, or the data sent from the sending side, for example, the sending side sends the handshake signal, handshake and signal first before sending data. The data transmission time parameter for the time being transmitted to the receiving side, a specific example not specifically limited.
Of course, not limited to this, in another option implementation method of the present embodiment, the parameter is not the above-mentioned correspondence relationship by the time when the unit interval cannot be 120, but a rule set in advance is obtained, and the above correspondence relationship is directly obtained. For example, when N = 1, the time interval corresponding to the directly promised bit 0 and bit 1, for example, 10 μs and 15 μs, respectively. Alternatively, the above correspondence can be received, and the present embodiment is not specifically limited.
In the case of the above correspondence relationship with the parameters according to the time, the time interval is adopted as the unit 120 and the data transmission side in advance, and the calculation method calculates the length of the time interval corresponding to the bit skew of N = N = n, the time interval Tm = etu + m * pdt (0 m ≤ ≤ 2n-1) for the bit skewer of the sending length n can be adopted, and the calculation method fixed time interval of the discussion in advance There are no specific restrictions. This data bit time interval, which is calculated through prior consultation, is the scalability of the transmission of guaranteed data, that is, no matter how N, the sending data side and the receiving side are the time intervals of the calculation data bits.
In the optional implementation plan of this application example, the exchange time for the update time parameter unit including the receiving device is updated with the parameter as the trigger time interval unit update, the default rule in the time parameter unit is updated, and the current time is updated. Replace the new time parameter with the new parameter time as the data transmission time parameter for the time being, the trigger time interval unit 201 under the new time parameter to get the length of each bit bit skewer and time in 2N N Relevant as per the interval. In this implementation plan, the data transmission device and the data reception device are completed through the determination of the new time parameter. Parameter of time when data should be used for table type data. The time parameter of the data transmission device can be changed precisely, the data processing capacity of the data receiving device, or a different type of data, improve the data processing efficiency. .
For the receiving unit 110, the Y + 1 received signal, and in particular, the first signal in the Y + 1 signal is a signal for starting the instruction data transmission, and Y + 1 is the total number of received signals.
In this embodiment, an instruction and a signal to start data transmission are the first data signal of data transmission, for example, the first data signal after reception of the scheduled time (same time, reception side and transmission side commitment confirmation) Or the handshake signal sent to the receiving side before sending data to the receiving end is the last signal in the handshake signal from the receiving and sending side as well as an instruction to start data transmission. In this embodiment, the handshake signal is transmitted to the transmission side at the start time of the instruction data transmission / reception side.
For example, the handshake signal parameters of the transmission side on the transmitting side, including time 2: handshaking etu and pdt, and at the time interval of the signal: t0, t1 t2, respectively, wine t0 = etu, t1 = etu + pdt can be determined according to the receiving side, t0 t 1 time etu and parameter pdt, or t 2 and wine in the second time interval set are also determined, 2t2 = 2etu, 2t1 = (Etu + pdt), according to the receiver side wine can also be confirmed t 2 hours etu and pdt parameter. Alternatively, the pdt parameter in terms of time etu can obtain t0 and t1 as long as through other relationships that t0 and t1 can also satisfy. Also, if there is only one time parameter directly and this time parameter is determined by one time interval in the K handshake signal, or if the three parameters are the time interval between signals through the K handshake The specific example of the three-hour parameter determined by the satisfaction relationship is already a luxury. If the time to overcome the handshake parameter through the K signal, the receiving side theory and the actual time parameter do not match, the data transmission accuracy is guaranteed.
The recording unit 140 uses a signal for instructing the start of data transfer as a first valid signal.
At the start of the decision unit 130, the decision Z signal to receive, whether to obtain the time interval at the start of the previous valid signal, at one time interval in the correspondence of the time interval unit 120 acquisition, Z = N, san, yo ......... Y.
The recording unit 140, the signal to determine valid, at the start of the unit Z signal, the Z signal in the case of one time interval in the correspondence to obtain the time interval at the start of the previous valid signal Enable recording signal.
According to the record, the valid signal acquisition unit 150 obtains a record of the unit X valid signal, where X <Y, and X is a positive integer.
For example, the transmission time parameter is now a 2-hour parameter, that is, the first time parameter etu and the second time parameter pdt, where etu = 10 μs, pdt = 10 μs. N = time of time, time parameter corresponding to bit skew (that is, 1-bit data or first-order bit skew), that is, a time interval corresponding to 0, etu, and a time interval corresponding to pdt, pdt. After the first signal validating the receiving unit 110 is confirmed, the second signal is received and the time interval between the start time of the signal and the start time of the first valid signal C1 is determined by the judgment unit 130. Since μs, the same time interval and the time interval for the first bit skewer 0 and 1 are not the same, the signal is a valid signal, the signal D for invalidating the signal recording is discarded.
Judgment unit will continue to judge the start time of the first signal and the time interval at the start of the first valid signal C 1 μs, the same time interval and the same time interval corresponding to the first bit skew, so the signal is The valid signal, the recording unit 140, the corresponding signal recording is the second valid signal C2, and at the start of the second valid signal C2.
Judgment unit 10 time signal continuation determination start time and second effective signal C 2 start time interval. Therefore, until reception ends until the judgment Y + 1 signal ends.
In the optional implementation plan of this application example, when the Z-th signal starts, the time interval at the start of the previous signal is larger than the default value. In other words, in this option implementation, after receiving the first valid signal, the initial signal at the start time of the hardware layer filtering drop-off signal of the receiving device and the start time of the previous signal is the default value. In response to the MCU unpleasant signal alone, the time interval between the current signal start time and the start of the previous signal can respond to the current signal of the equal default value (ie Z-th signal) can be increased and the subsequent valid Signal detection efficiency The work of the MCU is reduced and the load is negative.
In addition, the above-mentioned hardware layer filter can be employed in the following scheme: the first valid signal received from the receiver signal from the receiver T from the start of the chronograph, within the range of T + default value Time when no signal is received, T + default value From this moment to restart reception signal reception signal Zth (Z =), the start time of the same Z signal (Z =) and new T, above Repeat the procedure until the Y + 1th received signal.
Further, the minimum value of the time interval in the correspondence relationship of acquiring the default value described above as the acquisition unit interval 120. The time interval from the start of the current signal to the start time of the previous signal is the minimum value of the time interval in the corresponding relationship.
After the valid signal acquisition unit is effectively 150 X signals, the receiver device decodes the X valid signals and transmits the data on the transmission side. Therefore, in the optional implementation plan of the application of this embodiment, the receiving device includes: X determination to the determination unit effectively adjacent signal in the time interval between the start time of two signals, and in the obtained X-1 time interval in which , X ≤ Y + 1 and X is a positive integer; according to the acquisition relationship in the data acquisition unit, obtain a skew of 1 hour interval corresponding bits at each consecutive S time interval at the X-1 acquisition time interval, and S Bit skew of time interval transmission, of which the bit skew transmitted at this S time interval is 1 hour interval corresponding bit skew, under the situation of S>, this S time interval is the same, S is A positive integer, S ≦ X−1; the switching unit switches the bit skew of each continuous S time interval transmission at X-1 time intervals and transmits the bit skew at time intervals up to X-1.
In the option implementation method of the present embodiment, X-1 = n * S, where n is an integer and n is an integer, and this option implementation method, X signal transmission n * S is not a data bit that can be the same, There is no decoding problem due to extra signals.
Arbitrarily, the obtained X-1 time-interval transmission bit serial data is decoded, and the obtained X-1 time-interval transmission data is decoded to the bit group composition byte at the interdigit, resulting in X-1 time Interval data transmission.
In the optional implementation plan of the present application example, the test bit including the bit serial of the X-1 time interval transmission, for example, the test unit including the last byte and the receiving device includes the X-1 time interval transmission. Decrypt with bit skewer, get X-1 time interval data transmission, X-1 time interval data transmission data integrity check. Including, but not limited to, data integrity check, CRC odd / even check, digital signature, taking and checking, MAC checking, etc.
The specific operation of the execution of each unit in the present embodiment is further described in the specific description of the implementation plan of each option of the reference embodiment, no longer a luxury.

Example 13
One type of receiving device that provides this embodiment, a receiving method that can be used in the receiving device and drawn by the execution embodiment, and the data received in the receiving device according to the embodiment, that is, this embodiment In addition to the function of the receiving apparatus that can be explained in the above, the function of the data receiving apparatus is added.
The difference between the receiving device provided in the present embodiment and the receiving device described in the embodiment is that, in the twelfth embodiment, the receiving unit 110 receives the Y + 1 signal, the judging unit 130 sequentially determines whether each signal is valid, this embodiment Among them, the signal and the receiving unit 220 may be valid for the first time, all the received signals 230, that is, whether the signal is valid according to the judgment unit judgment. Compared to Example 12, the efficiency of the method provided in this example is even higher.
Figure 15 shows the structure of the receiving device provided by this embodiment. As shown in the figure, the receiving device is mainly: 2N 210, length to obtain the time interval unit. In N, there is a corresponding relationship between each bit bit skewer and the time interval, among them, 2N bit skewer is different, different skewer and bit corresponding time interval, N is one; receiving unit 220, for receiving As a signal to start transmission of the instruction data, the signal is first determined to be a valid signal and then received by the unit 230 which determines reception, and continues to receive the next unit 220 at the start of the valid signal before the start of the Zth signal. Whether the time interval is obtained or not, one time interval in the correspondence relationship of the time interval unit 210 acquisition, of which Z = 1, 2, 3, 4, ... Number, Y is a positive integer; Knit 230 judgment at the start of the Z signal enables the Z signal recording under the condition of one time interval in the correspondence of the unit 210 to obtain the time interval time interval at the start of the previous valid signal Signal; valid signal acquisition unit 250 records the result of unit 240 according to the record, X valid signal in reception unit 220 reception Y signal.
In the optional implementation plan of this application embodiment, the signal indicating the start of instruction data transmission, the first data signal of data transmission, and the last signal in the handshake signal of receiving unit 220 reception.
In the option implementation plan of this application example, the unit 220 or less method throughout the time interval is set to 2N length in each N bit bit skewer and time interval correspondence: final data transmission time parameter, Along the 2n N bit skewer, get the length of the reference number along the corresponding relationship with each bit and time interval.
In the optional implementation plan of this application example, the receiving device includes: X decision to the decision unit is effectively adjacent signal at the time interval between the start of two signals, and at X-1 time interval, among them, X ≤ Y + 1, and X is a positive integer; the data acquisition unit obtains a correspondence between the usage time interval of unit 220 acquisition and X-1 time interval for each continuous S time interval, and a 1-hour interval corresponding bit skewer. Bit skew of S time interval transmission, of which bit skew transmitted at this S time interval is a bit skew corresponding to one time interval, if S> 1, the time interval of S is the same, S Is a positive integer, S ≦ X−1; the switching unit is connected to the bit skew of each continuous S time interval transmission at X-1 time intervals to obtain a bit skew of X-1 time interval transmission.
In the optional implementation plan of this application example, the X-1 time interval data is transmitted to the inspection unit including the receiving device using the X-1 time interval transmission bit skew, and the X-1 time interval is transmitted. Data transmission data integrity check.
Among specific applications, the above-mentioned units of the receiving apparatus provided by the present embodiment will specifically describe the operation corresponding to the method execution described in the embodiment.

Example 14
According to the transmission method provided in the present embodiment, as shown in the figure, the following steps S1801 to S1806 are mainly performed for the transmission that provides the method according to the number of types in the present embodiment.
Step: K S1801 received signal.
K is a preset value, and K is an odd number and K. For example, when receiving the cumulative received signal so much, such as preset K =, the signal processing of the signal is performed and the K signal is transmitted through the method provided in this embodiment. Whether the relationship between the time intervals can be judged from the received data, that is, if the satisfied design relationship is after the K signal, the received data is the handshake signal of the received data from the indication as this K signal; , Receive signal pulse signal, ie high level pulse signal (letter along the rising), or low level pulse signal (signal along the falling), the pulse signal is square wave, square wave, triangular wave and other irregular The waveform is a combination of the above.
In this example, K signals are received and include at least one as follows:
Method 1: Detection up to K-th order low level pulse,
In this method, the terminal that can detect K-level low level pulses at a continuous high level, for example, after detecting a high level for a while, a low-level pulse is detected for a while, and after a recovery test to a high level, after a while In addition, once again, the electric detection flat pulse is low-level pulse that is continuously measured up to K times in this way,
Method 2: Detected up to K-th order high level pulse,
In this method, a terminal that can detect K-level high-level pulses that are continuously low-level, for example, after a low-level detection, for a while after detecting a high-level pulse for a while, and after recovering low-level detection again, after a while In addition, the high-level electric detection flat pulse is a level pulse that is high up to continuous measurement K in this way.
In the above method, the K signal jumps up, and the jumping width is clearly divided between convenience and noise signals.
Step S1802: Time interval between two for each adjacent to detection K signal.
In this embodiment, after the continuous reception signal detection KK, in the time interval between two signals adjacent to the signal, optionally when the signal of K is a low level signal of K at a continuous high level, low The time between the start of the pth signal and the start of the (p + 1) th electric signal is the time interval between the pth and the (p + 1) th signal, and the K signal is the same. The time from the start of the p + 1 high level signal to the beginning of the p + 1 high level signal is the time interval between the p and p + 1 signals. , That 1 ≤ p ≤ K-1, and p through the implementation of one option as a natural number, the method starts at the start of pulse signal detection, thereby accurately locating two adjacent signals at the time interval of the start time.
Step S1803: Satisfactory design relationship between the determination first time interval and the second time interval.
In this embodiment, one optional implementation method is as follows. In step S1803, the one time interval is a time interval between the start of the i-th signal and the start of the i-1th signal, and the second time interval is the i-th signal. The time interval between the beginning and the start of the i + 1th signal, where i =, 4 ..., 2j, j = (K-1) /, where K is odd and K; sample When K =, the time interval between the two adjacent to each signal is i = 4 and the first time interval is between the first signal and the start of the second signal. Time interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1 i = 4; sometimes the first time interval Is the time interval between the third signal and the fourth signal start time, the mark is t2, the second time interval is the time interval between the fourth signal and the letter signal start time, the notation is wine . This design-related technology depends on the so-called satisfaction design relationship between the first time interval and the second time interval of judgment, and the satisfaction design relationship between judgment t0 t1 and between t2 and wine. As long as the user's experience is confirmed or the parameters at the time of execution are indeed limited, the guarantee is satisfied. As an option implementation method, t 1 = a * t0 and wine = a * t 2; or t 1 = (a + b) * t0 and wine = (a + b) * t 2; t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, where a, b, and c are one natural number, for example, a =, the same design relationship There are many kinds, here is a luxury.
Step S1804: A confirmed first time interval set and / or a second time interval set.
Among them, j is the first set j time interval including the second time interval, j is the two time interval including the second time interval set, j = (K-1) /, K is odd and K. When not by taking i, at least one of the first time intervals of the series, with the first time interval and the second time interval of the series, which produces the K-1 hour interval of the K signal generation The first time interval set is similarly selected from a plurality of different second time intervals, and at least one second time interval set, for example, K = e.g., At each signal generation interval, the first time t0, t2, and The second time interval t1, the wine takes t0 at this time, and takes the first time interval set as t2, t1, the wine sets for the first time in the second time, this embodiment is the limit first time interval The number of time intervals in the set or the second time interval set can determine such a scheme through at least one of the first time interval set and / or the second time interval set, as the time interval classification process I do.
Step S1805: If the one time interval and the second time interval satisfaction design relationship, the first time interval is at least one time interval in the group and / or at least one second time interval is determined in the second time interval group. Data transmission time reference.
In step S1805, at least one time interval in the first time interval group and / or at least one second time interval in the second time interval group, specifically, at least two in the first time interval set. At the first time interval, at least two second time intervals are determined in the second time interval group according to the parameter of the time for which the current data has been lost, and at least one second time interval and second in the first time interval group. At least one second time interval co-determined data transmission time parameter, and the first time interval and the second time interval are adjacent to the group of time intervals.
In the present embodiment, the first time interval between the i-th signal and the (i-1) th signal, the i-th signal and the (i + 1) -th signal in the determined first time interval set and second time interval set. When the second time interval between them is satisfied with the design relationship, the signal of K is judged and the effective handshake signal is then determined by the first time interval set, or the second time interval set, or the first time interval set or the second The parameter generation rule at the promised time in advance at the time interval set and the data transmission side, the parameter during the time of final data transmission, while the parameter generation rule at the promised time is the only premise of each data bit coding guarantee Under the parameter confirmation, you can choose any kind of method under
For example, when I = K, the time interval of occurrence between two adjacent to your signal is i = 4, the first time interval is between the first signal and the second signal Time interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal start time, the notation is t 1 i = 4; sometimes the time interval of the first time The time interval between the third signal and the fourth signal start time, the notation is t2, the second time interval is the time interval between the fourth signal and the first signal start time, By way of example, the details of how the data transmission time parameter is determined for the time being at least one time interval in the group of one time interval and / or at least one second time interval in the group of the second time interval as follows.
The optional implementation method as one of the present embodiment, select t0 and t2 by the first time interval set, the parameter including the time of the time transmission of the time interval set for the time being, the parameter first time parameter etu and The second time parameters pdt, etu and pdt are t0 and t2 only as shown in the table, according to the value of etu and pdt t0 t2, the arbitrary calculation method is obtained, and any of sampleability, etu and pdt adopted below Acquired such a calculation method, of course, but not limited to the following calculation methods:
etu = t0, pdt = (t0-t2) / 5;
etu = t0 + t2, pdt = (t0 + t2) / 10;
etu = t0 + t2 / 2, pdt = (t0-t2) / 5;
etu = t2, pdt = (t0-t2) / 15;
........
In the present embodiment, the selection t0 option is implemented as another type of system, and the parameter including the time of the time transmission of the first time interval set final data transmission by the first time interval set is the first parameter time parameter etu and the first time parameter set. The two-time parameters pdt, etu and pdt are only t0, according to the values of etu and pdt, obtain the method of arbitrary calculation of the value of t0, and acquire the calculation method of sampling, one of etu and pdt below Of course, not limited to the following calculation methods:
etu = t0, pdt = t0 / 5;
etu = 2 * t0, pdt = t0 / 10;
etu = t0 / 2, pdt = t0 / 5;
etu = t0 / 3, pdt = t0 / 15;
........
The implementation of the option of selecting another type of method as the present embodiment, t 1 and wine by the second time interval set, the second time interval set final parameters including the time of the data transmission for the time being, the parameter first Time parameter etu and second time parameter pdt, etu and pdt are t1 and wine is only, according to the value of etu and pdt, through the wine value t1 arbitrary calculation method, sampleability, etu and pdt adopted below Acquire any of the calculation methods, of course, but not limited to the following calculation methods:
etu = t1, pdt = (t1-t3) / 5;
etu = t1 + t3, pdt = (t1 + t3) / 10;
etu = t1 + t3 / 2, pdt = (t1-t3) / 5;
etu = t3, pdt = (t1-t3) / 15;
........
In this embodiment, the t 1 option is implemented as another type of method, and the parameter including the time of the second time interval set final data transmission time is determined by the second time interval set, the parameter first time parameter etu And the second time parameter pdt, etu and pdt t 1 only, t1 value depending on the value of etu and pdt, get any calculation method, calculate the sampleability, etu and pdt any one below Of course, the following calculation methods are not limited:
etu = t1, pdt = t1 / 5;
etu = 2 * t1, pdt = t1 / 10;
etu = t1 / 2, pdt = t1 / 5;
etu = t1 / 3, pdt = t1 / 15;
........
In this embodiment, the selection t0 option is implemented as another type of system, the first time interval set, the wine selected as the first time interval set, the one time interval set or the second time interval set is determined for the time being. Parameters include etu and second time parameters pdt, etu and pdt t0 only and the first time of the parameter includes genotype time and wine, according to the value of etu and pdt, acquire the method of arbitrary calculation of the value of t0 wine Acquire any of the following calculation methods, sampleability, etu and pdt adoption, and of course, the following calculation methods:
etu = t0, pdt = t3 / 5;
etu = 2 * t0, pdt = t3 / 10;
etu = t0 / 2, pdt = t3 / 5;
etu = t0 / 3, pdt = t3 / 15;
etu = t0 + t3, pdt = t0 + t3 / 5;
etu = t0 / 3 + t3, pdt = t0 + t3 / 15;
........
Similarly, when K = Nichi, there is an adjacent Nashi between two signals, and when the time interval is i =, one time interval is between the start of the first signal and the second signal. Time interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal start time, the notation is t 1 i = 4; sometimes the first time interval Is the time interval between the third signal and the fourth signal start time, the notation is t2, the second time interval is the time interval between the fourth signal and the fifth signal start time, I = 1 hour interval from the 5th signal and the 6th signal start time, the notation is t4, the second time interval is the 6th signal and the 7th signal In the time interval between the signal start times, its mark is t5; optional t0 t2, t4 first time interval set is also selected t1, wine and t5 second time interval set At least two first time intervals in a set of time intervals are determined for the time being by the data transmission time parameter, and in the second time interval group, at least two second time current data transmission time interval determination parameters are also set in the first time interval. At least one second time interval in the group and at least one second time interval in the group of at least one time interval is jointly determined for the time being the data transmission time parameter, adjacent to the time etu not one time interval and the second time interval, and the parameter pdt The acquisition method is the only one that adopts another calculation method, the first time interval group and / or the second time interval group can be arbitrarily acquired, and the specific acquisition method can be referred to as K = do not do.
When K = san, the time interval of occurrence between two adjacent to her signal, sometimes when i =, the 1 hour interval is the time interval between the first signal and the second signal The notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1; by example, at least one time interval into a group of one time intervals as follows: And / or at least one second time interval determination in the second time interval group and detailed description in the manner of data transmission time parameter for the time being.
In the present embodiment, the selection t0 option is implemented as another type of system, and the parameter including the time of the time transmission of the first time interval set final data transmission by the first time interval set is the first parameter time parameter etu and the first time parameter set. The two-time parameters pdt, etu and pdt are only t0, according to the values of etu and pdt, obtain the method of arbitrary calculation of the value of t0, and acquire the calculation method of sampling, one of etu and pdt below Of course, not limited to the following calculation methods:
etu = t0, pdt = t0 / 5;
etu = 2 * t0, pdt = t0 / 10;
etu = t0 / 2, pdt = t0 / 5;
etu = t0 / 3, pdt = t0 / 15;
........
In this embodiment, the t 1 option is implemented as another type of method, and the parameter including the time of the second time interval set final data transmission time is determined by the second time interval set, the parameter first time parameter etu And the second time parameter pdt, etu and pdt t 1 only, t1 value depending on the value of etu and pdt, get any calculation method, calculate the sampleability, etu and pdt any one below Of course, the following calculation methods are not limited:
etu = t1, pdt = t1 / 5;
etu = 2 * t1, pdt = t1 / 10;
etu = t1 / 2, pdt = t1 / 5;
etu = t1 / 3, pdt = t1 / 15;
........
In the present embodiment, the specific implementation method of the above-determined immediate data transmission time parameter is a sample implementation method, and at least 2 in the first time interval set of the parameter generation rule according to other time not excluded in the present application. At least one first time interval or at least one second time interval in the first time interval group or at least two second time intervals in the first time interval or in the second time interval group. Implementation method for two-hour interval, final data transmission time parameter.
In this embodiment, the first time interval set and / or the second time interval set is determined, and the etu time parameter and pdt are used to guarantee the transmission of the guarantee data every time, and to the receiving side the etu and pdt. , Stability and accuracy of data transmission every time, handshake information sent to the receiving side also frequently before data transmission avoids the new time parameters etu and pdt values, and the frequency difference is an error due to continuous addition of multiple characters Effective for preventing transmission and transmission. When the difference between the clock and reception time parameters is large, sampling by the reception side causes reception errors and communication efficiency degradation.
In this embodiment, one optional implementation method, if the design relationship does not satisfy the one time interval and the second time interval, the design relationship continues, ie, the procedure of the received handshake signal, that is, return to step S1801.
Through the data transmission method of this embodiment, handshake in the information by the received data every time, the new parameters of the time, guarantee the time parameters of the sending and receiving sides from start to finish, adopt the stability and color of the guarantee data transmission Detecting the rise of all signals, or along the fall, easily get all the signals adjacent to each other, thereby accurately locating the two adjacent signals The time interval between the start times is determined by whether the time interval between the determination signals satisfies the design interval, the handshake signal whether the received signal is valid, the determination process is accurate, and the success rate is high, with a high success rate. Determine time interval and / or second time interval Determine first time interval set and / or second time interval set one time interval set and / or second time interval set etu time parameter and pd Therefore, the guaranteed data transmission is always sent to the sending side and the receiving side is unified with etu and pdt, the data transmission stability and accuracy every time, often the receiving side also sent to the sending side before data transmission The handshake information avoids the new time parameters etu and pdt values, and the difference in the weekly frequency is accumulated error due to continuous addition of multiple characters. Effective for prevention of transmission. Technical problems of sampling error, reception error, and communication efficiency.

Example 15
According to the method for providing the number of one kind in this embodiment, as shown in the figure, the data transmission method of this embodiment is mainly from step S1901 to step S1903.
Step S1901: Final time parameter.
In this embodiment, a kind of optional implementation method, the time parameter is the first time parameter and / or the second time parameter is the first time of the lieutenant general of this embodiment for ease of explanation. Remember etu parameter, pdt second time parameter description, first time parameter etu and second time parameter pdt average representative time value, eg etu = comma 1 second, pdt = 0.01 second, value send data According to the side, the receiving side, this time parameter determines the time interval of the handshake, according to the signal transmission receiving side, confirming the handshake of the received signal, of course, only one parameter with time alone, the time parameter is In the present embodiment, the description is given by way of example, and only the time parameter is taken as an example, and the time parameter is determined to be used in the first time interval group or the second time interval group, but the parameters do not exclude much time.
According to the procedure, S1902: Time 1 hour interval parameter determination group and 2 hour interval group.
Among them, one optional embodiment in the present embodiment, the first time interval is j first time interval including the first time interval, j second time interval including the second time interval set, At the transmission K handshake signal, the time interval between the start of the i-th signal and the start of the i-1 signal, Ti-1 is remembered, i, the second time interval is the transmission K handshake signal, At the time interval between the start of the i-th signal and the start of the i + 1-th signal, Ti is remembered, i + 1, during i =, 4 ..., 2j, j = (K-1 ) /, K is odd and K.
What needs to be explained in this embodiment is that the first time interval Ti-1, i in the first time interval set and the second time interval Ti, i + 1 in the second time interval set are constant. Through this relationship, the effectiveness of the design relationship can be guaranteed and the handshake signal is received at the receiving side. After this handshake signal, the first time interval Ti-1, i and the second time interval Ti, i + 1 The received data signal from the design relation, judgment and handshake signal instructions; next, each one time interval Ti-1, i and first time parameter etu and / or second time parameter in the first time interval set pdt constant design relationship, the receiver receives the received signal, after shaking hands, through the same design relationship, the first time parameter received first time parameter e command and / or second time pdt parameter received by the receiver By first time parameter etu and / or second time parameter Bit data corresponding to the calculation time interval of pdt transmission.
In this embodiment, the first time interval Ti-1, i in the 1-hour interval set and the second time interval Ti, i + 1 in the second time-interval set, many types that can include a certain design relationship. In the following, a sample method will be described, which also includes various design relationships between each time interval Ti-1, i-1 in the first time interval set, and the constant of etu and / or second time parameter pdt.
An optional embodiment as an example of this embodiment is that when K = going as an example, the time interval between occurrences of every two adjacent to the signal becomes i = i = In time interval T1, the time interval between the first signal and the second signal start time, the mark is t0, the second time interval T2, the second signal and the third signal Time interval between start times, expressed as t 1 i = 4; sometimes time, 1st time interval T3, 4 times expressed as the time interval between the third signal and the 4th signal start time The t2, second time interval to the team, please let the fourth signal and your signal start time in the time interval, notation is wine. At this time, take t0, t2 first time interval set, t1, wine meet the second time interval, fill between the first time interval and the second time interval, so-called design relationship, between t0 and t1 Thus, the experience of this design engineer is determined by the satisfied design relationship between the wines and t 2, or the actual runtime parameters are determined. As an option implementation method, t 1 = a * t0 and wine = a * t 2; or t 1 = (a + b) * t0 and wine = (a + b) * t 2; t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, where a, b, and c are one natural number, for example, a =, the same design relationship There are many kinds, here is a luxury.
Hereinafter, taking the first time interval t0 and t2 of the first time interval set as an example, each one time interval Ti-1, i t0, t2 in the first time interval set and the first time parameter etu and / or Explain the default relationship of the second time parameter pdt constant:
According to the first time interval t0 t2, the time parameter generation rule generation of the transit deposit in the one-time parameter etu and the second time parameter pdt is taken as an example using tu and t2 as one of the following The following calculation method is not limited to the generation time rule, of course, the design parameters are obtained:
t0 = a * etu;
t2 = x * a * etu;
Among them, a is a natural number and x is a rational number, so the receiving side uses the same design time to calculate the t0 parameter generation rule and etu t 2.
Alternatively, according to the one hour interval t0 t2, the time parameter generation rule generation through the one hour parameter etu and the second time pdt deposit parameter, adopting t0 and t2 to acquire one of the following calculation methods Of course, not only the design but also the time parameter generation rules below the total calculation method:
t0 = a * etu + b * pdt;
t2 = x * a * etu + b * pdt;
Among them, a and b are natural numbers, and x is a rational number, so pdt etu t 2 when the receiving side is calculated as a t0 parameter generation rule using the same design time.
Alternatively, according to the one hour interval t0 t2, the time parameter generation rule generation through the one hour parameter etu and the second time pdt deposit parameter, adopting t0 and t2 to acquire one of the following calculation methods Of course, not only the design but also the time parameter generation rules below the total calculation method:
t0 = a * etu + b * pdt;
t2 = a * etu + x * b * pdt;
Among them, a and b are natural numbers, and x is a rational number, so pdt etu t 2 when the receiving side is calculated as a t0 parameter generation rule using the same design time.
Similarly, when K = 7, 7 signals are adjacent to each other and 6 time intervals are generated. When i = 2, the first time interval T1, 2 is the first signal. And start the time interval between the time for the second signal and become 0, labeled t, the second time interval T2,3 is the time for the second signal and the third signal Starts with a time interval between 1 and t, and becomes t; when i = 4, the first time interval T3,4 is the time between times for the third and fourth signals Start the interval, 2 marked t, the second time interval T4,5 starts the time interval between the time for the 4th and 5th signals, 3 marked t When i = 6, the first time interval T5,6 starts the time interval between the time for the 5th signal and the 6th signal, becomes 4 and becomes t, 2 time interval T6,7 starts the time interval between the time for the 6th signal and the 7th signal, t5; At this time, t0, t2 and t4 are one hour interval set, t1, wine and t5 second time interval set, second time interval set t1, wine and t5 and one hour interval set One hour parameter etu and / or second time pdt, depending on t0, t2 and t4 respectively, satisfying design relationship, i.e. between t0, between t1 t2 and wine, or between t4 and t5, with satisfying design relationship The time parameter generation rule is determined through the deposit parameters. The first time interval t0, t2 and t4 values of the first time interval set are adopted through the design rules. t0, t 2 and t4, the first time parameter etu and the second time parameter pdt in the time parameter generation rule generation for transit deposits in etu as an example, t0, t 2 and t4 adopted Of course, the default time parameter generation rule is to calculate Not limited to:
t0 = a * etu;
t2 = x * a * etu;
t4 = 2x * a * etu;
Among them, a is a natural number, x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rule, t2, t4 etu.
Alternatively, one time interval t0, t2 and t4, the first time parameter etu and the second time pdt deposit parameter, the time parameter generation rule generation, t0, t2, t4 adoption of any calculation method below Of course, not only the design but also the calculation method below the time parameter generation rule:
t0 = a * etu + b * pdt;
t2 = x * a * etu + b * pdt;
t4 = 2x * a * etu + b * pdt;
Among them, a and b are natural numbers, and x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rules, t 2 and t 4 etu and pdt.
Alternatively, one time interval t0, t2 and t4, time parameter generation rule generation through the first time parameter etu and the second time pdt deposit parameter, and one of the calculation methods below t0, t2 and t4 adoption is acquired Of course, not only the design but also the calculation method below the time parameter generation rule:
t0 = a * etu + b * pdt;
t2 = a * etu + x * b * pdt;
t4 = a * etu + 2 x * b * pdt;
Among them, a and b are natural numbers, and x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rules, t 2 and t 4 etu and pdt.
In the present embodiment, the specific implementation method of the first time interval group and the second time interval group of the above-described fixed data transmission in the present embodiment is a sample implementation method, and parameter generation is performed at other times not excluded in the present application. Rules The first time parameter etu and / or the second time parameter pdt established The default relationship between the other first time interval and the second time interval without also excluding the first time interval implementation scheme of the first time interval set.
In this embodiment, the transit time parameter etu and / or the first time interval set to pdt, thereby guaranteeing every time data transmission to the sending side, and the receiving side to be unified with etu and pdt, the stability of data transmission every time Accuracy, often the handshake sent by the sender before data transmission avoids new information time etu and pdt parameter values, the frequency difference is accumulated error due to continuous addition of multiple characters, effective for preventing transmission and clock and reception time When the difference in parameters is large, there is a problem of reception error and communication efficiency decrease due to sampling by the receiving side.
Step S1903: The generated transmission is a handshake signal of K.
As an option of this embodiment, it is implemented by one type of method, and in the concrete implementation, the generated transmission includes the handshake of K: The first interval of the signal interval pair and the two-hour interval set generated transmission is shaken by K Signal; among them, the default relationship that satisfies the interval between the first time interval and the second time interval in K's handshake signal.
In this embodiment, K is a preset value, K is an odd number, and the signal is a received pulse signal, that is, a high-level pulse signal (signal along the rise), or a low-level pulse signal (along the fall) Signal), pulse signals are square waves, square waves, triangle waves, and other irregular waveforms.
In this embodiment, K signals are generated and transmitted, including at least one as follows:
Method 1: Generate Kth order low level pulse,
In this method, the high-level and transmitting side continuously triggers K times low-level pulse, for example, after the first time interval of high level triggers, triggers a low-level pulse once, and then goes through a recovery trigger high-level state again, After the second time interval, the trigger pulse is one low level pulse. Such a method is repeated K times low level pulse, the one time interval is the time interval between the start of the i-th signal and the start of the i-1 signal. The second time interval is the time interval between the start of the i-th signal and the start of the i + 1-th signal, of which i =, 4, ..., 2j, j = (K-1) /, K Is odd and K.
When the sampleability is K =, and the time interval between the two adjacent to each signal is i = 4, the first time interval is the first signal and the second signal. The time interval between the start times, the notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1 i = 4; the hour, the first time Is the time interval between the third signal and the fourth signal start time, the notation is t2, and the second time interval is the time interval between the fourth signal and the second signal start time. Transmit side continuous trigger 5 times low level pulse, with high level in wine: followed by trigger high level for some time, then trigger first low level pulse, and again after recovery trigger high level state, after t0 After a low electrical trigger flat pulse at the 2nd, and again after a high level state of recovery trigger, trigger the degree of t 3 -After a high level pulse, and again after the recovery trigger high level state, after t2, the trigger 4th low level pulse, and again after the recovery trigger high level state, after the wine, the inspired low level pulse is , Such a method, continuous low-level pulse, and the first time interval and the second time interval satisfaction design relationship, for example, t 1 = a * t 0 and wine = a * t 2; or t 1 = ( a + b) * t0 and wine = (a + b) * t 2; or t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, of which a, b, c is one natural number, for example, a =, the design relationship is various, here is another form of lavish, effective handshake signal,
Method 2: Generate high level pulses K times,
In this method, the high-level pulse triggered K times to the low level on the transmitting side is, for example, after the first time interval of the low level is triggered, the high-level pulse is triggered once again, and the recovery trigger low level is passed through again. After the two-hour interval, the trigger pulse is one high pulse pulse. This method is repeated K times high level pulse, the one-time interval is the time interval between the start of the i-th signal and the start of the i-1 signal. The second time interval is the time interval between the start of the i-th signal and the start of the i + 1-th signal. Of these, i =, 4, ..., 2j, j = (K-1) /, Mr. K Is odd and K.
When the sampleability is K =, and the time interval between the two adjacent to each signal is i = 4, the first time interval is the first signal and the second signal. The time interval between the start times, the notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1 i = 4; the hour, the first time Is the time interval between the third signal and the fourth signal start time, the notation is t2, and the second time interval is the time interval between the fourth signal and the second signal start time. The sender sends the high level pulse, which is triggered continuously to the low level: followed by the trigger low level for a while, then the trigger first high level pulse, and then the recovery trigger low level state again, t0 After a high electrical trigger flat pulse in the second time, and again after a recovery trigger low level state, trigger after t 1 After a high level pulse, and again through the recovery trigger low level condition, after t2, after the trigger high level pulse, and again through the recovery trigger low level condition, after the wine The high level pulse is a series of high level pulses repeated in this manner, and the design relationship satisfying the first time interval and the second time interval, for example, t 1 = a * t 0 and wine = a * t 2; t 1 = (a + b) * t0 and wine = (a + b) * t 2; or t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, Among them, a, b, c are one natural number, for example, a =, the design relationship is various, here is another word that forms a luxury, a valid handshake signal,
In the above method, the K signal jumps up, and the jumping width is clearly divided between convenience and noise signals.

Example 16
The data processing equipment of this embodiment is provided, and as shown in the figure, this data processing equipment is included: reception module, judgment module, time processing module and data processing module.
The receiving module is used to receive the K signal.
K is a preset value, K is an odd number and K. For example, in the case of preset K = reception module accumulated reception signal, the received signal processing is performed in the judgment module, time processing module and data processing module. Whether the received data can be judged from the relationship of the time interval between the K signals through the data processor, that is, if the satisfied design relationship is the received data after the K signal, the received data from the indication as this K signal Handshake signal; when the signal receives a pulse signal, that is, a high level pulse signal (signal along the rise), or a low level pulse signal (signal along the fall), the pulse signal is a square wave, a square wave , Triangle waves and other irregular waveforms are a combination of the above different waveforms.
In this embodiment, the receiving module includes at least one as follows to receive K signals:
Method 1: The receiving module is detected in the K-th order low level pulse,
In this scheme, a continuous K low level pulse at a high level that can detect the receiving module is detected, for example, after a period of time of the receiving module measured high level, once a low level pulse, and also a high level After a recovery test to the state, after a while, once again low level pulse, K level that can be continuously measured by the method such as receiving module, low level pulse,
Method 2: Receiving module detected up to K-th order high level pulse,
In this method, K high level pulses during continuous low level that can be detected by the receiving module are, for example, receiving module measurement, after a low level for a while, once detected high level pulse, and again recovered low level detection status After a while, a level pulse with the highest degree of detection again, a level pulse with a high degree up to K that can be continuously measured by a method such as a receiving module,
In the above method, the K signal jumps up, and the jumping width is clearly divided between convenience and noise signals.
The decision module is used to detect the time interval between two adjacent in the K signal,
In this embodiment, after receiving the receiving module continuous K signal, optionally, in the time interval between two signals adjacent to the judging module detection K signal, the K signal is continuously converted to a low level signal of K. At the time, the time between the start of the decision module confirmation pth low electric ordinary zip code and the start of the p + 1 low level signal is the time interval between the pth and p + 1 signals, and similarly, The time between the start of the (p + 1) th high level signal from the time of the start of the (p + 1) th high level signal is the time between the start of the (p + 1) th high level signal and the (k + 1) th time. The time interval between the signals, 1 ≦ p ≦ K−1, and one optional embodiment as a natural number p, the time interval between two signal start times adjacent to the beginning of each module measurement pulse signal through judgment To get accurately and quickly.
Judgment module to determine the satisfaction of the design relationship between the first time interval and the second time interval.
In this example, one optional embodiment, the first time interval is the time interval between the beginning of the i-th signal and the beginning of the i-th signal, and the second time interval is the beginning of the i-th signal. In the time interval between the start of the i + 1th signal, i =, 4 ..., 2j, j = (K-1) /, where K is odd and K; When K =, when the time interval between two adjacent to the signal becomes i = 4, the first time interval is the time between the first signal and the start of the second signal. In the interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal, the notation is t 1 i = 4; sometimes the first time interval is 3 The time interval between the first signal and the fourth signal start time, the mark is t2, the second time interval is the time interval between the fourth signal and the letter signal start time, the notation is wine. This design-related technology depends on the so-called satisfaction design relationship between the first time interval and the second time interval of judgment, and the satisfaction design relationship between judgment t0 t1 and between t2 and wine. As long as the user's experience is confirmed or the parameters at the time of execution are indeed limited, the guarantee is satisfied. As an option implementation method, t 1 = a * t0 and wine = a * t 2; or t 1 = (a + b) * t0 and wine = (a + b) * t 2; t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, where a, b, and c are one natural number, for example, a =, the same design relationship There are many types, here is a luxury; when the decision module judgment is related to the first time interval and the second time interval satisfaction design, the judgment K signal is effective and a handshake signal.
For the time processing module, a fixed first time interval set and / or a second time interval set, a first set j time interval including the first time interval, j two time intervals including the second time interval set, j = ( K-1) /, K is odd and K.
In the first time interval and the second time interval of the series, which also produces the K-1 time interval of the processing module K signal generation by the time not taken i select at the first time interval of several different from the time processing module At least one first time interval group is selected, and at the same time, at least one second time interval set by selecting a plurality of different second time intervals, for example, K = 1 hour t0, t2, and second time interval t1, wine now takes the time t0 processing module and takes the first time interval set as t2, t1, wine takes the second time interval set In the present embodiment, the number of time intervals in the limit first time interval set and the second time interval set are all j, and at least one time, the processing module can determine this method through the first time interval Pair and / or second time interval pair And processes to classify the time interval to.
If one time interval and second time interval satisfaction design relationship, the time processing module transmits at least one time interval to the first time interval group and / or at least one second time interval to the second time interval group for the time being. Ginseng,
Among them, the processing module according to time, at least one time interval in the first time interval group and / or at least one second time interval in the second time interval group, the parameters of the data transmission time for the time being, specifically, At least two first times in the first time interval set in the processing module first time interval set by time, at least two second time intervals in the second time interval group, or at least one time interval in the first time interval group If at least one second time interval is assigned to the second time interval group, the data transmission side promises the time parameter generation rule, and the first time interval and the second time interval are adjacent to each other.
In the present embodiment, the first time interval between the i-th signal and the (i-1) th signal, the i-th signal and the (i + 1) -th signal in the determined first time interval set and second time interval set. When the second time interval between is satisfied with the design relationship, the signal of K determines the valid handshake signal at this time, by the at least two first time intervals in the first time interval set in the processing module, or by the second Send data with at least two second time intervals in the time interval group, or at least one second time interval in the first time interval group or at least one second time interval in the first time interval group Promise time parameter generation rules, and the first time interval and the second time interval are adjacent to each other. Tsu DOO under sole premise of the coding method, determine the parameters of the time can choose any type of system.
For example, when I = K, the time interval of occurrence between two adjacent to your signal is i = 4, the first time interval is between the first signal and the second signal Time interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal start time, the notation is t 1 i = 4; sometimes the time interval of the first time The time interval between the third signal and the fourth signal start time, the notation is t2, the second time interval is the time interval between the fourth signal and the first signal start time, Taking this as an example, then the details of the method of determining the data transmission time parameter for the time being at least one time interval in the first time interval group and / or at least one second time interval in the second time interval group.
Optional implementation method as one of the present embodiment, selected as the time processing module t0 t2 By the first time interval set, the parameter including the time of the time of the one time interval set final data transmission is the parameter first time parameter etu and second time parameter pdt, etu and pdt are t0 and t2 only, according to the value of etu and pdt, the value of t0 t2 is obtained by any calculation method, sampleability, etu and pdt adopted Acquired such a calculation method, of course, but not limited to the following calculation methods:
etu = t0, pdt = (t0-t2) / 5;
etu = t0 + t2, pdt = (t0 + t2) / 10;
etu = t0 + t2 / 2, pdt = (t0-t2) / 5;
etu = t2, pdt = (t0-t2) / 15;
........
Another optional implementation method as the present embodiment, selected as the time processing module t0 The first time interval set, the parameter including the time of the time of the one time interval set final data transmission is the parameter first time parameter etu And the second time parameters pdt, etu and pdt are t0 only, the etu and pdt values can be obtained through any calculation method according to the value of t0, and one of the calculation methods below etu and pdt adopted Of course, not limited to the following calculation methods:
etu = t0, pdt = t0 / 5;
etu = 2 * t0, pdt = t0 / 10;
etu = t0 / 2, pdt = t0 / 5;
etu = t0 / 3, pdt = t0 / 15;
........
In this embodiment, another optional implementation method, the time processing module selection t 1 and the wine is determined by the second time interval set, the second time interval set final parameter including the time of the time of data transmission is the parameter 1st time parameter etu and 2nd time parameter pdt, etu and pdt are t1 and wine is only display, according to the value of etu and pdt through the value of wine win t1 arbitrary calculation method, sampleability, etu Acquire any of the following calculation methods using pdt, and of course:
etu = t1, pdt = (t1-t3) / 5;
etu = t1 + t3, pdt = (t1 + t3) / 10;
etu = t1 + t3 / 2, pdt = (t1-t3) / 5;
etu = t3, pdt = (t1-t3) / 15;
........
In this embodiment, another optional implementation method, the time processing module selection t 1 The second time interval set is determined by the second time interval set. The parameter etu and the second time parameter pdt, etu and pdt are t1 only, the value of t1 depending on the value of etu and pdt, get the method of arbitrary calculation, sampleability, etu and pdt any one of the following Acquired the calculation method of, of course, but not limited to the following calculation methods:
etu = t1, pdt = t1 / 5;
etu = 2 * t1, pdt = t1 / 10;
etu = t1 / 2, pdt = t1 / 5;
etu = t1 / 3, pdt = t1 / 15;
........
When K = san, the time interval of occurrence between two adjacent to her signal, sometimes when i =, the 1 hour interval is the time interval between the first signal and the second signal The notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1; by example, at least one time interval into a group of one time intervals as follows: And / or at least one second time interval determination in the second time interval group and detailed description in the manner of data transmission time parameter for the time being.
In the present embodiment, the selection t0 option is implemented as another type of system, and the parameter including the time of the time transmission of the first time interval set final data transmission by the first time interval set is the first parameter time parameter etu and the first time parameter set. The two-time parameters pdt, etu and pdt are only t0, according to the values of etu and pdt, obtain the method of arbitrary calculation of the value of t0, and acquire the calculation method of sampling, one of etu and pdt below Of course, not limited to the following calculation methods:
etu = t0, pdt = t0 / 5;
etu = 2 * t0, pdt = t0 / 10;
etu = t0 / 2, pdt = t0 / 5;
etu = t0 / 3, pdt = t0 / 15;
........
In this embodiment, the t 1 option is implemented as another type of method, and the parameter including the time of the second time interval set final data transmission time is determined by the second time interval set, the parameter first time parameter etu And the second time parameter pdt, etu and pdt t 1 only, t1 value depending on the value of etu and pdt, get any calculation method, calculate the sampleability, etu and pdt any one below Of course, the following calculation methods are not limited:
etu = t1, pdt = t1 / 5;
etu = 2 * t1, pdt = t1 / 10;
etu = t1 / 2, pdt = t1 / 5;
etu = t1 / 3, pdt = t1 / 15;
........
Similarly, when K = Nichi, there is an adjacent Nashi between two signals, and when the time interval is i =, one time interval is between the start of the first signal and the second signal. Time interval, the notation is t0, the second time interval is the time interval between the second signal and the third signal start time, the notation is t 1 i = 4; sometimes the first time interval Is the time interval between the third signal and the fourth signal start time, the notation is t2, the second time interval is the time interval between the fourth signal and the fifth signal start time, I = 1 hour interval from the 5th signal and the 6th signal start time, the notation is t5, the second time interval is the 6th signal and the 7th The time interval between the signal start times of t6, mark t6; time t0 pick processing module, t2 as the first time interval t5 set also select t1, wine and t6 second time interval , By the processing module first time interval set by the time, at least two first time intervals in the first time interval set by the current data transmission time parameter, the second time interval group is also determined by at least two second time intervals. At least one second time interval in the group of one time interval and at least one second time interval in the group of the second time interval, and a time parameter for losing data for the time being, and no time adjacent to the first time interval and the second time interval, The parameter etu and pdt acquisition methods are the only ones that adopt a time processing module and acquire one time interval group and / or second time interval group through another calculation method, and specifically acquire K = 5 I can refer to the idea of time, and I will not mention it here anymore.
When K = san, the time interval of occurrence between two adjacent to her signal, sometimes when i =, the 1 hour interval is the time interval between the first signal and the second signal The notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1; by example, at least one time interval into a group of one time intervals as follows: And / or at least one second time interval determination in the second time interval group and detailed description in the manner of data transmission time parameter for the time being.
In the present embodiment, the selection t0 option is implemented as another type of system, and the parameter including the time of the time transmission of the first time interval set final data transmission by the first time interval set is the first parameter time parameter etu and the first time parameter set. The two-time parameters pdt, etu and pdt are only t0, according to the values of etu and pdt, obtain the method of arbitrary calculation of the value of t0, and acquire the calculation method of sampling, one of etu and pdt below Of course, not limited to the following calculation methods:
etu = t0, pdt = t0 / 5;
etu = 2 * t0, pdt = t0 / 10;
etu = t0 / 2, pdt = t0 / 5;
etu = t0 / 3, pdt = t0 / 15;
........
In this embodiment, the t 1 option is implemented as another type of method, and the parameter including the time of the second time interval set final data transmission time is determined by the second time interval set, the parameter first time parameter etu And the second time parameter pdt, etu and pdt t 1 only, t1 value depending on the value of etu and pdt, get any calculation method, calculate the sampleability, etu and pdt any one below Of course, the following calculation methods are not limited:
etu = t1, pdt = t1 / 5;
etu = 2 * t1, pdt = t1 / 10;
etu = t1 / 2, pdt = t1 / 5;
etu = t1 / 3, pdt = t1 / 15;
........
In the present embodiment, the specific implementation method of the above-determined immediate data transmission time parameter is a sample implementation method, and at least 2 in the first time interval set of the parameter generation rule according to other time not excluded in the present application. At least one first time interval or at least one second time interval in the first time interval group or at least two second time intervals in the first time interval or in the second time interval group. Implementation method for two-hour interval, final data transmission time parameter.
In this embodiment, the time processing module determines the first time interval set and / or the second time interval set by the etu time parameter and the pdt, so that the transmission side of the guarantee data is transmitted every time, and the etu and pdt on the receiving side. In this way, the stability and accuracy of data transmission each time, the handshake information sent to the sending side also frequently before the data transmission avoids the values of the new time parameters etu and pdt, and the frequency difference Effective error accumulation by consecutive addition of multiple characters, effective for transmission prevention When the difference between the clock and reception time parameters is large, sampling by the reception side, reception errors, communication efficiency problems.
In this embodiment, an optional implementation method, a design relationship that does not satisfy the one time interval and the second time interval, the above design relationship, and a handshake signal receiving module that continues to receive instructions.
The data processing module receives data according to the time parameter.
As an example of this, one optional embodiment, the receiving module is a time interval between the start times of two signals adjacent to the receiving X signal determination X signal, and at an X-1 time interval, of which X Is a positive integer, X>1; the data processing module receives the time parameter as follows, to obtain this X signal, specifically the data processing module, X-1 time interval with each successive S time interval 1 Obtain N data bits corresponding to time interval, S data bits for time interval transmission, N data bits to obtain S time interval transmission data bits, of which S> 1 situation Below, the time interval of S is the same, of which X and S are all positive integers, S X-1 ≤.
In this example, one type of optional embodiment, data acquisition is negotiated by the receiving side adoption and data sending side calculation method, current data transmission time parameter fixed data bit, current data receiving side is discussed and data The calculation method of the transmission side, when N = n, the calculation method of the time interval of transmission data bits m is m = etu + m * pdt (in which 0 m ≤ ≤ 2n-1 and etu Time parameter, pdt second time parameter, etu = 10 μs, pdt = 30 μs), that is, the calculation method is 10 μs + 3 * 30 μs = 100 μs at the time interval of data bits. If the data reception device receives a time interval of μs, the calculation m is passed, that is, the data bits corresponding to the same time interval are every time.
In this embodiment, according to one optional implementation method, the data processing module receives the parameter etu, the second time parameter pdt, and the data transmission side in advance with the promised encryption / decryption rule received data; data processing 2N different numerical values and time interval correspondences, including different numerical value corresponding to time interval, including N time data parameters, including time based on parameter received data including time Ichi.
Data processing module 1st time parameter etu, 2nd time parameter pdt and data transmission side include promise encryption / decryption rule in advance, correspondence relationship of time interval different from 2N number of N bit data, promise encryption The encoding / decryption rules can be used for N number of data bits with different numbers.
If N = 1, the N data bits with different numbers are 0, 1, then
0 = etu, 1 = etu + pdt, and etu ≠ etu + pdt, or
0 = 2etu, 1 = etu + 2pdt, and 2etu ≠ etu + 2pdt,
......
If N = 2, N data bits of different numbers are contained in 00, 01, 10, 11
00 = etu, 01 = etu + pdt, 10 = etu + 2pdt, 16 = etu + 3pdt, and etu ≠ etu + pdt ≠ etu + 2pdt ≠ etu + 3pdt, or
00 = 2etu, 01 = etu + 2pdt, 10 = etu + 2.5pdt, 16 = 1.3etu + 3pdt,
And 2etu ≠ etu + 2pdt ≠ etu + 2.5pdt ≠ 1.3etu + 3pdt,
......
Similarly, when N = san, different numeric data bits include: N 001, 000, 010, 2011, Hyaku, 101, 110, 111, at this time, the first time parameter etu and the second time parameter pdt In the above sample, the promise encryption / decryption rule is obtained in advance in the time interval corresponding to 2N different numerical values including the N-bit data bag. It's already a luxury.
Depending on the data processing module and the data transmission side, the time interval corresponding to 2N different numerical values of the parameter including the one-hour parameter etu and the second time pdt N-bit data, among them, the time interval corresponding to different numerical values is different according to the method promised in advance By transmitting data transmission on the transmitting side by receiving the time interval of realization through different data bits corresponding to different time intervals of reception separately.
In the optional implementation method of this embodiment, the time processing module is preceded by the data transmitted by the data processing module, with a time interval corresponding to the parameter N bits, with a different numerical value. If it is not an N-bit compatible time interval, it is N 1

Adopting data as an option, negotiating with the receiving side, N = n as in the calculation method on the transmitting side and the data bit calculation time interval, and the calculation method of the time interval of transmission data bit m = etu + m * pdt (in which 0 m ≤ ≤ 2n-1, etu is a one hour parameter, pdt second time parameter, etu = 10 μs, pdt = 30 μs), that is, at every data bit time interval The calculation method is 10 μs + 30 μs = 30 μs, other pre-consultation can be adopted, the calculation method fixed time interval, this implementation is not specifically limited. The data bit time interval for which the calculation method is calculated through prior consultation, the scalability of guaranteed data transmission, that is, no matter how N, the data sending side and the data receiving side also calculate the data bit time interval.
Another option implementation method as an example of this application. The data receiving side also adopts and the data sending side decides the memory list in advance, or the data bit time interval, adopts the data processing module, the search list is fixed and the data bit time interval is obtained, the data The efficiency of the bit time interval.
In the option implementation method of the present embodiment, X-1 = n * S, where n is an integer and n is an integer, and this option implementation method, X signal transmission n * S is not a data bit that can be the same, There is no decoding problem due to extra signals.
In the optional implementation method of this embodiment, as shown in FIG. 10, the module replacement time parameter including the data processing facility update time parameter, that is, the new time parameter for replacing the deposit in the rule with the current use time parameter is the new time reference number. As the data transmission time parameter for the time being; the data processing module decodes the received X signal in the time interval corresponding to the N bit of the numerical value due to the difference in re-acquisition, that is, the time parameter currently used is each consecutive S at the time interval of X-1. Get N bit corresponding to 1 hour interval in time interval, S data bit for transmission of time interval, N bit bit to get data of S time interval transmission obtained. In this implementation plan, the data receiver side completes the discussion with the data transmission side by determining the new time parameter. A parameter for the time when data should be used for certain types of data. By changing the time parameter on the data transmission side, the data processing capacity data can be refined by the receiving device, or the data of different types, improving the efficiency of data processing.
In the optional implementation method of this embodiment, after the last received data bit is completed, the receiving module receives A as a signal (Z is an integer), and the handshake signal that is the same as the clear signal is another specified signal. The format signal is the same as the end signal, whether the data can be processed, the module data bit reception end.
In the optional implementation scheme of this embodiment, the receiving module receives the signal after the last received data bit has been completed, or after the completed reception A receives a signal, and the module receives the test data bit for reception, Receive data to determine if it is completely correct. The inspection data bits are inspection data calculated by a parity method such as MAC inspection, parity, and taking and inspection.
In the optional implementation method of this embodiment, as shown in the figure, it receives Z for the signal for the filter module including the data processing equipment, gets the interference of the Z signal, and is the Z out of the receiving module from the X signal transmission X.
The technical scheme provided by this application example can be identified, and the data processing module receives the final received waveform data bits using only two wires at the time interval of the received waveform by the data processing module. When applied, the volume of electronic equipment is effectively small.
Handshake in the information by the received data every time through the data processing module of the present embodiment, the new time parameter guarantees the sender and receiver time parameters from beginning to end, the guarantee data transmission stability and color, Signal pulse signals are easy to pass and separate noise signals to detect all signal rises or along the decline, easily get all signals at the start, thereby starting exactly two adjacent signals Determine the time interval between the time intervals Judgment whether the time interval between the signals meets the design relationship, the handshake signal whether the received signal is valid, accurately determine the process quickly and with a high success rate for one hour Determine the interval and / or the second time interval Determine the first time interval set and / or the second time interval set to the one time interval set and / or the second time interval set etu time parameters And pdt guarantees that data transmission is guaranteed every time on the sending side and the receiving side is unified with etu and pdt, each time the data transmission is stable and accurate, often before the data transmission, the receiving side also sends it to the sending side. The handshake information avoids the new time parameters etu and pdt values, the difference in the frequency of the week is a cumulative error due to the continuous addition of multiple characters, effective for preventing transmission, when the difference between the clock and the next collection time parameter is very large, the receiving side Due to sampling error, reception error, communication efficiency technical problem.

Example 17
A data processing facility of this embodiment is provided and includes this data processing facility as shown in FIG. 1: a second time parameter module, a second time processing module, a second signal generation and dispatch module.
Among them, the second time parameter module is used to determine the time parameter.
In this embodiment, a kind of optional implementation method, the time parameter is the first time parameter and / or the second time parameter is the first time of the lieutenant general of this embodiment for ease of explanation. Remember etu parameter, pdt second time parameter description, first time parameter etu and second time parameter pdt average representative time value, eg etu = comma 1 second, pdt = 0.01 second, value send data According to the side, the receiving side, this time parameter determines the time interval of the handshake, according to the signal transmission receiving side, confirming the handshake of the received signal, of course, only one parameter with time alone, the time parameter is In the present embodiment, the description is given by way of example, and only the time parameter is taken as an example, and the time parameter is determined to be used in the first time interval group or the second time interval group, but the parameters do not exclude much time.
For the second time processing module, the second time interval set is a first set j time interval including the first time interval among the parameter determination time interval set and the second time interval set by the first time. Including j two-hour intervals.
In this embodiment, a kind of optional embodiment, the first time interval is between the start of the i-th signal and the start of the i-1 signal when the handshake signal of the second signal generation dispatch module dispatch K At the time interval, Ti-1 is memorized, i, 2nd time is the first time when the handshake signal of shipping K, Ti memorized at the time interval between the start of the i-th signal and the start of the i + 1-th signal , I + 1, inside, i =, 4 ..., 2j, j = (K-1) /, K is odd and K.
What needs to be explained in this embodiment is that the first time interval Ti-1, i in the first time interval set and the second time interval Ti, i + 1 in the second time interval set are constant. Through this relationship, the effectiveness of the design relationship can be guaranteed and the handshake signal is received at the receiving side. After this handshake signal, the first time interval Ti-1, i and the second time interval Ti, i + 1 The received data signal from the design relation, judgment and handshake signal instructions; next, each one time interval Ti-1, i and first time parameter etu and / or second time parameter in the first time interval set pdt constant design relationship, the receiver receives the received signal, after shaking hands, through the same design relationship, the first time parameter received first time parameter e command and / or second time pdt parameter received by the receiver By first time parameter etu and / or second time parameter Bit data corresponding to the calculation time interval of pdt transmission.
In this embodiment, the first time interval Ti-1, i in the 1-hour interval set and the second time interval Ti, i + 1 in the second time-interval set, many types that can include a certain design relationship. In the following, a sample method will be described, which also includes various design relationships between each time interval Ti-1, i-1 in the first time interval set, and the constant of etu and / or second time parameter pdt.
An optional embodiment as an example of this embodiment is that when K = going as an example, the time interval between occurrences of every two adjacent to the signal becomes i = i = In time interval T1, the time interval between the first signal and the second signal start time, the mark is t0, the second time interval T2, the second signal and the third signal Time interval between start times, expressed as t 1 i = 4; sometimes time, 1st time interval T3, 4 times expressed as the time interval between the third signal and the 4th signal start time The t2, second time interval to the team, please let the fourth signal and your signal start time in the time interval, notation is wine. At this time, take t0, t2 first time interval set, t1, wine meet the second time interval, fill between the first time interval and the second time interval, so-called design relationship, between t0 and t1 Thus, the experience of this design engineer is determined by the satisfied design relationship between the wines and t 2, or the actual runtime parameters are determined. As an option implementation method, t 1 = a * t0 and wine = a * t 2; or t 1 = (a + b) * t0 and wine = (a + b) * t 2; t 1 = (c * a + b) * t0 and wine = (c * a + b) * t 2, where a, b, and c are one natural number, for example, a =, the same design relationship There are many kinds, here is a luxury.
Hereinafter, taking the first time interval t0 and t2 of the first time interval set as an example, each one time interval Ti-1, i t0, t2 in the first time interval set and the first time parameter etu and / or Explain the default relationship of the second time parameter pdt constant:
According to the first time interval t0 t2, the time parameter generation rule generation of the transit deposit in the one-time parameter etu and the second time parameter pdt is taken as an example using tu and t2 as one of the following The following calculation method is not limited to the generation time rule, of course, the design parameters are obtained:
t0 = a * etu,
t 2 = x * a * etu,
Among them, a is a natural number and x is a rational number, so the receiving side uses the same design time to calculate the t0 parameter generation rule and etu t 2.
Alternatively, according to the one hour interval t0 t2, the time parameter generation rule generation through the one hour parameter etu and the second time pdt deposit parameter, adopting t0 and t2 to acquire one of the following calculation methods Of course, not only the design but also the time parameter generation rules below the total calculation method:
t0 = a * etu + b * pdt,
t 2 = x * a * etu + b * pdt,
Among them, a and b are natural numbers, and x is a rational number, so pdt etu t 2 when the receiving side is calculated as a t0 parameter generation rule using the same design time.
Alternatively, according to the one hour interval t0 t2, the time parameter generation rule generation through the one hour parameter etu and the second time pdt deposit parameter, adopting t0 and t2 to acquire one of the following calculation methods Of course, not only the design but also the time parameter generation rules below the total calculation method:
t0 = a * etu + b * pdt,
t 2 = a * etu + x * b * pdt,
Among them, a and b are natural numbers, and x is a rational number, so pdt etu t 2 when the receiving side is calculated as a t0 parameter generation rule using the same design time.
Similarly, when K = 7, 7 signals are adjacent to each other and 6 time intervals are generated. When i = 2, the first time interval T1, 2 is the first signal. And start the time interval between the time for the second signal and become 0, labeled t, the second time interval T2,3 is the time for the second signal and the third signal Starts with a time interval between 1 and t, and becomes t; when i = 4, the first time interval T3,4 is the time between times for the third and fourth signals Start the interval, 2 marked t, the second time interval T4,5 starts the time interval between the time for the 4th and 5th signals, 3 marked t When i = 6, the first time interval T5,6 starts the time interval between the time for the 5th signal and the 6th signal, becomes 4 and becomes t, 2 time interval T6,7 starts the time interval between the time for the 6th signal and the 7th signal, t5; At this time, t0, t2 and t4 are one hour interval set, t1, wine and t5 second time interval set, second time interval set t1, wine and t5 and one hour interval set One hour parameter etu and / or second time pdt, depending on t0, t2 and t4 respectively, satisfying design relationship, i.e. between t0, between t1 t2 and wine, or between t4 and t5, with satisfying design relationship The time parameter generation rule is determined through the deposit parameters. The first time interval t0, t2 and t4 values of the first time interval set are adopted through the design rules. t0, t 2 and t4, the first time parameter etu and the second time parameter pdt in the time parameter generation rule generation for transit deposits in etu as an example, t0, t 2 and t4 adopted Of course, the default time parameter generation rule is to calculate Not limited to:
t0 = a * etu;
t2 = x * a * etu;
t4 = 2x * a * etu;
Among them, a is a natural number, x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rule, t2, t4 etu.
Alternatively, one time interval t0, t2 and t4, the first time parameter etu and the second time pdt deposit parameter, the time parameter generation rule generation, t0, t2, t4 adoption of any calculation method below Of course, not only the design but also the calculation method below the time parameter generation rule:
t0 = a * etu + b * pdt,
t 2 = x * a * etu + b * pdt,
t4 = 2x * a * etu + b * pdt,
Among them, a and b are natural numbers, and x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rules, t 2 and t 4 etu and pdt.
Alternatively, one time interval t0, t2 and t4, time parameter generation rule generation through the first time parameter etu and the second time pdt deposit parameter, and one of the calculation methods below t0, t2 and t4 adoption is acquired Of course, not only the design but also the calculation method below the time parameter generation rule:
t0 = a * etu + b * pdt,
t 2 = a * etu + x * b * pdt,
t4 = a * etu + 2 x * b * pdt,
Among them, a and b are natural numbers, and x is a rational number, so the receiving side uses the same design time to calculate t0 parameter generation rules, t 2 and t 4 etu and pdt.
In the present embodiment, the specific implementation method of the first time interval group and the second time interval group of the above-described fixed data transmission in the present embodiment is a sample implementation method, and parameter generation is performed at other times not excluded in the present application. Rules The first time parameter etu and / or the second time parameter pdt established The default relationship between the other first time interval and the second time interval without also excluding the first time interval implementation scheme of the first time interval set.
In this embodiment, the transit time parameter etu and / or the first time interval set to pdt, thereby guaranteeing every time data transmission to the sending side, and the receiving side to be unified with etu and pdt, the stability of data transmission every time Accuracy, often the handshake sent by the sender before data transmission avoids new information time etu and pdt parameter values, the frequency difference is accumulated error due to continuous addition of multiple characters, effective for preventing transmission and clock and reception time When the difference in parameters is large, there is a problem of reception error and communication efficiency decrease due to sampling by the receiving side.
The second signal transmission module generates and transmits K handshake signals.
As an option of this embodiment, it is implemented by one type of method, and in the concrete implementation, the generated transmission includes the handshake of K: The first interval of the signal interval pair and the two-hour interval set generated transmission is shaken by K Signal: Among them, it is necessary to satisfy the interval between the first time interval and the second time interval in the handshake signal of K, and to satisfy the one time interval and the second time interval throughout the embodiment with reference to the above default relationship. Explanation of design relations.
In this embodiment, K is a preset value, K is an odd number, and the signal is a received pulse signal, that is, a high-level pulse signal (signal along the rise), or a low-level pulse signal (along the fall) Signal), pulse signals are square waves, square waves, triangle waves, and other irregular waveforms.
In the present embodiment, at least one of the second signal generation dispatch module generation transmission including the K signal has the following scheme:
Method 1: Transmitting a second-signal transmission module to transmit a K-th order low level pulse,
In this scheme, the second signal generation dispatch module continuously triggers high level K times low level pulses, for example, the second signal generation dispatch module subsequently triggers high level after the first time interval, trigger once low level pulse, and again After a second time interval, after the recovery trigger high level state, the trigger once low level pulse is repeated in such a manner K times low level pulse, one time interval is the beginning of the i-th signal and the i-th signal. The time interval between the start of one signal, the second time interval, and the time interval between the start of the i-th signal and the start of the (i + 1) -th signal, where i = , 2j, j = (K-1) /, K is odd and K.
When the sampleability is K =, and the time interval between the two adjacent to each signal is i = 4, the first time interval is the first signal and the second signal. The time interval between the start times, the notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1 i = 4; the hour, the first time Is the time interval between the third signal and the fourth signal start time, the notation is t2, and the second time interval is the time interval between the fourth signal and the second signal start time. The second signal generation dispatch module triggers the low level pulse, which triggers continuously to the high level: the second signal generation dispatch module follows the trigger high level for a while, then the trigger first low level pulse, and again Recovery trigger High power level, after passing t0, triggered second low level pulse And then again to trigger the high voltage state, after passing through t1, trigger the third low level pulse and then recover to trigger the high voltage state again. After passing through t2, the fourth low-level pulse is triggered, then it is restored to triggering a high voltage state, and after passing through t3, the fifth low-level pulse is restored. In this way, 5 low level pulses can be generated continuously in this way, and the first time interval and the second time interval satisfy the default relationship, for example, T1 = a * t0 and t3 = a * t2; or t1 = (a + b) * t0 and t3 = (a + b) * t2; or t1 = (c * a + b) * t0 and * t2 of t3 = (c * a + b), where a, b, c ≧ 1, natural numbers, for example, a = 2, this default relationship can be various, Don't tell me anymore Form a valid handshake;
Method 2: Transmits the K-th order high level pulse by generating the second signal transmission module,
In this scheme, the second signal generation and dispatch module triggers K times high level pulses at a continuous low level, for example, the second signal generation and dispatch module followed by the trigger low level after a first time interval, the trigger one high level pulse, and again After the recovery trigger low level state, after the second time interval, the high level pulse once again triggers such a method, the high-level pulse is repeated K times, and the one-time interval is the beginning of the i-th signal and the i-th signal. The time interval between the start of one signal, the second time interval, and the time interval between the start of the i-th signal and the start of the (i + 1) -th signal, where i = , 2j, j = (K-1) /, K is odd and K.
When the sampleability is K =, and the time interval between the two adjacent to each signal is i = 4, the first time interval is the first signal and the second signal. The time interval between the start times, the notation is t0, the second time interval is the time interval between the second signal and the third signal, and the notation is t 1 i = 4; the hour, the first time Is the time interval between the third signal and the fourth signal start time, the notation is t2, and the second time interval is the time interval between the fourth signal and the second signal start time. The second signal generation dispatch module triggers at the continuous low level, the second high frequency pulse, and the second signal generation dispatch module triggers after the low level for a while, then the trigger first high level pulse, and again Recovery trigger Low-powered flat state, after passing through t0, triggered the second high voltage pulse , Then again recovering to trigger a low level condition, after passing through t1, to trigger a third high voltage pulse and then recovering to trigger a low level condition again After passing through t2, recovering from triggering the 4th high voltage pulse and then again triggering the low level condition, and after passing through t3, the 5th high voltage pulse In this way, five high voltage pulses can be generated in succession, and the first time interval and the second time interval satisfy the default relationship. For example, t1 = a * t0 and t3 = a * t2; or t1 = (a + b) * t0 and t3 = (a + b) * t2; or t1 = (c * a + b ) * T0 and t3 = (c * a + b) * t2, where a, b, c ≧ 1 natural numbers, for example, a = 2, this default relationship can be various, Do n’t say this anymore, Form a valid handshake.
In the above method, the K signal jumps up, and the jumping width is clearly divided between convenience and noise signals.
Each time the received data through the handshake every time before the information is a new time parameter, guarantee the sender and receiver time parameters from beginning to end, guarantee data transmission stability and accurate pulse signal transmission, adopt the signal Hold and separate the noise signal, all signals along the rise or decrease of the detection trigger, can easily get all the signals at the start, so exactly two adjacent signals between the start The time interval between the time interval and the time interval between the decision signals is not satisfied with the design relationship, the decision whether the received signal is valid, the handshake signal whether it is valid, the first time interval with high success rate in the process of accurately and quickly judging Alternatively, the second time interval is determined by determining the first time interval set and / or the second time interval set, the first time interval set and / or the second time interval set by the etu time parameter and pdt. For each guarantee data transmission, the sending side and the receiving side are unified with etu and pdt, and the stability and accuracy of the data transmission each time. The transmission handshake avoids the values of the new time parameters etu and pdt, accumulates errors due to continuous addition of multiple characters in the weekly frequency, and is effective for preventing transmission.When the difference between the clock and reception time parameters is large, sampling is performed by the reception side. Reception errors, communication efficiency technical problems.

Any process or method described in the flowcharts or described herein by other aspects is a module of code of executable instructions, one or more steps that includes steps for implementing one or more specific logic functions or processes. And the scope of the preferred embodiment of the present invention includes other implementations, where the order shown or described may not be followed, and the functions involved are essentially simultaneous. Or the functions may be performed in the reverse order. This should be understood by those skilled in the art to which the embodiments of the present invention belong.

Each part of the present invention may be realized by hardware, software, firmware, or a combination thereof. In the embodiments described above, the steps or methods may be implemented by software or firmware that is stored in a memory and that executes the system with appropriate instructions. For example, when implemented by hardware, as in the other embodiments, for example, a discrete logic circuit having a logic gate circuit for realizing a logic function for a data signal, and a dedicated integration having an appropriate combinational logic gate circuit It may be realized by any one of the well-known techniques in the art such as a circuit, a programmable gate array (PGA), a field programmable gate array (FPGA), or a combination thereof.

A person skilled in the art can complete the implementation of all or some of the steps included in the methods in the above embodiments by commanding the correlating hardware by a program, which is stored on a computer readable storage medium. Alternatively, when the program is executed, one step or combination of steps in the method embodiments is executed.

Furthermore, each functional unit in each embodiment of the present invention may be integrated in one processing module. Each unit may be physically present individually. Two or more units may be integrated in one module. The integrated modules described above may be realized by hardware or may be realized by software function modules. If the integrated module is implemented in the form of a software functional module and sold or used as an independent product, it may be stored on a single computer readable storage medium.

The storage medium may be a read only memory (ROM), a magnetic disk, an optical disk, or the like.

In the description of the present invention, the description referring to terms such as “one embodiment”, “some embodiments”, “examples”, “specific examples”, or “some examples” Specific features, configurations, materials, or characteristics described in connection with the embodiments or examples are included in at least one embodiment or example of the present invention. In this specification, exemplary depictions of the above terms are not necessarily indicative of the same embodiments or examples. In addition, the specific features, configurations, materials, or characteristics described can be combined appropriately in any one or more embodiments or examples.

As mentioned above, although the Example of this invention was shown and demonstrated, said Example is only an illustrative description and does not limit this invention. Those skilled in the art can make various changes, modifications, changes and modifications to these embodiments within the scope of the present invention without departing from the principle and spirit of the present invention. The scope of the invention is limited by the claims and their equivalents.

Detailed Description of the Invention

  This application claims priority based on the Chinese patent application whose application number is CN201501055517.8 and whose application date is September 21, 2015, and uses the whole of the said Chinese patent application for this application.

  The present invention relates to the field of electronic technology, and more particularly, to a data transmission method and apparatus, and a data reception method and apparatus.

  Currently, with rapid development of electronic products, external interfaces are becoming congested. Typical wired external interfaces include a USB interface and a DOCK interface. However, these interfaces require at least three or more wires for communication and charging, occupy a large volume in the electronic device, and require more hardware support. Therefore, in this technical field, in order to reduce the cost of hardware and the volume of electronic equipment, a two-line communication technology means that can realize data transmission using only two lines is desired.

  The present invention is intended to solve one of the above problems. The present invention provides the following technical means.

According to a first aspect of the present invention, there is provided a data transmission method, which comprises determining a time parameter for transmitting current data, and according to the time parameter, 2 ^N pieces included in N-bit data. The time interval corresponding to the different numerical values, N ≧ 1, the step of acquiring the data bit string to be transmitted, and the data bit string On the other hand, the grouping is performed so that the data of each group becomes N bits, and the data of the group is indicated at the time interval corresponding to the numerical value of the data of each group based on the acquired correspondence relationship. Transmitting the group data.

According to a second aspect of the present invention, there is provided a data receiving method, wherein the data receiving method includes determining a time parameter for transmitting current data, receiving X signals, and receiving X signals. Determining a time interval between each start time of two adjacent signals in the signal to obtain X-1 time intervals, where X is a positive integer and X>1; Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and a numerical value transmitted in the S time intervals. And the numerical value transmitted in S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data, and S> 1 If in S time intervals Interval are the same time, both X and S is a positive integer, and comprising the steps is S ≦ X-1, N ≧ 1, a.

According to a third aspect of the present invention, there is provided a data transmission device, the data transmission device comprising: a time parameter determination unit for determining a time parameter for transmitting current data;
Based on the time parameter, it is for obtaining the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval, where the time intervals corresponding to the different numerical values are different and N ≧ 1 A time interval acquisition unit that is
A data bit string acquisition unit that acquires a data bit string of a current transmission target and performs grouping on the data bit string so that each group of data has N bits;
And a transmission unit for transmitting the data of the group so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group based on the acquired correspondence.

Further, according to a fourth aspect of the present invention, there is provided a data receiving device, the data receiving device comprising: a time parameter determining unit for determining a time parameter for transmitting current data;
Receiving X signals, determining a time interval between the start times of two adjacent signals in the X signals, and obtaining X-1 time intervals; Where X is a positive integer and X> 1, the receiving unit;
Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and a numerical value transmitted in the S time intervals. The numerical value transmitted in S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data. Yes, if S> 1, the data acquisition unit includes the same time interval in S time intervals.

  As can be seen from the technical means provided by the present invention described above, according to the technical means provided by the present invention, it is possible to transmit information using a transmission time interval, and the data transmission device can transmit between two signals. By indicating the data information transmitted in the time interval, data communication is possible only with two lines, and the data transmission device and the data reception device can communicate with only two communication interfaces.

  Hereinafter, in order to explain the technical means according to the embodiments of the present invention more clearly, the drawings necessary for the description of the embodiments will be briefly described. Of course, the drawings in the following description are merely some embodiments of the present invention, and those skilled in the art can obtain other drawings from these drawings on the premise that they do not perform creative labor.

3 is a flowchart illustrating a data transmission method provided by Embodiment 1 of the present invention. It is a schematic diagram which shows the waveform which can respond | correspond to one time interval for every data group provided by Example 1 of this invention, and can respond also to several time intervals. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 2 provided by Example 1 of the present invention. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 1 provided by Example 1 of this invention. It is a schematic diagram which shows the waveform which transmits the data bit string 0011100100 when N = 3 provided by Example 1 of this invention. 6 is a flowchart illustrating a data receiving method provided by Embodiment 2 of the present invention. It is a schematic diagram which shows the structure of the data transmitter provided by Example 3 of this invention. It is a schematic diagram which shows the structure of the data receiver provided by Example 4 of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, technical means according to embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention. Of course, the described embodiments are merely some embodiments, not all embodiments. A person skilled in the art, based on the embodiments of the present invention, belongs to the protection scope of the present invention in any other embodiments obtained on the premise of not performing creative labor.

  In the description of the present invention, “first” and “second” are only for the purpose of explaining the purpose, and are understood to mean to indicate / imply relative importance, quantity, and position. must not.

  Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.

Example 1
According to the present embodiment, a data transmission method is provided. FIG. 1 is a flowchart of one data transmission method that can be selected in this embodiment. The execution subject in the embodiment of the present invention may be a transmitting end that transmits data.

  As shown in FIG. 1, the data transmission method mainly includes the following steps 101 to 105.

  Step 101: Determine a time parameter for transmitting current data.

  In one selectable embodiment of the present example, the time parameter for transmitting the current data may be preset and determined in the data transmission end. Further, the data transmission end may be determined by obtaining from another device. Furthermore, the data transmission end may be calculated and determined by setting in advance. The present invention does not limit a method for determining a time parameter for transmitting current data. Finally, any method that can determine the time parameter for transmitting the current data belongs to the protection scope of the present invention.

  In one selectable embodiment of the present example, this step is a selectable step.

Step 102, obtain the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval according to the time parameter. Here, the time intervals corresponding to different numerical values are different, and N ≧ 1.

As one selectable embodiment of the present embodiment, “correspondence between 2 ^N different numerical values included in N-bit data and time intervals is obtained according to the time parameter. Here, time intervals corresponding to different numerical values are obtained. May be understood as follows.

To obtain the corresponding relationship between the bit string and the time interval the 2 ^N length in a bit string is N, wherein, the 2 ^N bit strings are different from each other, different time interval corresponding to and different bit strings N ≧ 1. For example, when N = 1, each bit string in a bit string having two lengths of 1 is 0 and 1, respectively, and when N = 2, four bit strings having a length of 2 The bit strings in are respectively 00, 01, 10 and 11, and when N = 3 or 3 or more, it may be referred to the case where N = 2, so it will not be described in detail here.

In one selectable embodiment of the present embodiment, “2 ^N different numerical values included in N-bit data” may be understood as follows. For example, if the N = 1, 1-bit data includes 2 ¹ different numbers, 0, 1, respectively, if it is N = 2, 2-bit data includes 2 ^two different numbers, respectively 00, 01, 10, and 11. It may be understood as follows with respect to “obtaining correspondence between 2 ^N different numerical values included in N-bit data and time intervals according to the time parameter”. For example, when N = 1, a time interval corresponding to 0 is acquired according to the time parameter, and a time interval corresponding to 1 is acquired according to the time parameter. When N = 2, the time interval corresponding to 00 is acquired according to the time parameter, the time interval corresponding to 01 is acquired according to the time parameter, the time interval corresponding to 10 is acquired according to the time parameter, and the time A time interval corresponding to 11 is obtained according to the parameters. Of course, when N is another value, it is the same as the above understanding method, so it will not be described in detail here.

In one selectable embodiment of the present embodiment, the data transmission end can calculate the time interval corresponding to the numerical value by a calculation method agreed in advance with the data reception end. For example, when N = n, the calculation method of the time interval corresponding to the numerical value m may be as follows. That is, the time interval corresponding to the numerical value m = etu + m * pdt (where 0 ≦ m ≦ 2 ⁿ −1, etu is the first time parameter, and pdt is the second time parameter. For example, etu = 10 μs. , Pdt = 30 μs). That is, the calculation method of the time interval corresponding to the numerical value 11 may be 10 μs + 3 * 30 μs = 100 μs. With this selectable embodiment, a time interval corresponding to a numerical value can be calculated. Of course, the present invention may determine the time interval by other pre-agreed calculation methods, and the present invention is not limited thereto. By calculating a time interval corresponding to the numerical value by a calculation method agreed in advance, it is possible to ensure the scalability of data transmission. That is, regardless of what the value of N is, it is possible to calculate the correspondence between numerical values and time intervals that are different at the transmitting end and the receiving end.

  As another selectable embodiment of the embodiment of the present invention, the data transmission end may determine a time interval corresponding to the numerical value according to a list previously agreed and stored with the data reception end. If the time interval corresponding to the numerical value is determined by querying the list, the efficiency of obtaining the time interval corresponding to the numerical value can be improved.

  As another selectable embodiment of the embodiment of the present invention, the data transmission end calculates a time interval corresponding to the numerical value by a calculation method agreed in advance with the data reception end, and then the data transmission end. By referring to the list stored in advance, it is determined whether or not the time interval corresponding to the numerical value obtained by the calculation is within the reception range of the data receiving end. If the time interval corresponding to the numerical value is obtained by calculating the time interval corresponding to the numerical value and then obtaining the time interval corresponding to the numerical value by referring to the list, the expandability of the data transmission can be improved on the assumption that the receiving end normally receives.

  Step 103: Acquire the current data bit string to be transmitted.

  In one selectable embodiment of the present invention, the sending end of the data may itself generate the current transmission target data bit string or receive the current transmission target data bit string from another device. May be. The present invention is not limited to the current method of acquiring the data bit string to be transmitted. Finally, any method that can acquire the current data bit string to be transmitted belongs to the protection scope of the present invention.

  As one selectable embodiment of the present invention, the data transmission end may be a single relay device that relays communication between the data reception end and another device (hereinafter referred to as a first terminal). . In this case, the data transmission end obtains a data bit string to be transmitted currently through a method including the following steps. In other words, step 103a receives the first data via the first interface. Step 103b, decoding the first data based on the protocol supported by the first interface to obtain the first data bit string to be transmitted. When the data transmission end is a relay device, it may have two communication interfaces. For example, it has a first interface and a second interface, the first interface is an interface that communicates with a first terminal, the second interface is an interface that communicates with a data receiving end, The interface may be an existing universal interface such as a USB interface, an audio interface, a serial port, Bluetooth, WiFi, NFC, or a wired interface, and receives the first data from the first terminal. Thus, you may connect to a 1st terminal via the said 1st interface. The first terminal may be a device such as a mobile phone, a computer, or a PAD. The first data may be data transmitted by a mobile phone, a computer, or a PAD. At the same time, depending on the interface type of the first interface, the first data received based on the supporting protocol may be decoded. For example, the first interface decodes the first data based on the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, the NFC protocol, etc., and a data bit string corresponding to the first data. To get. The data bit string is a first data bit string to be currently transmitted (that is, a data bit string to be currently transmitted). The second interface may be an interface connected to an electronic payment device (that is, a data receiving end), and transmits data to the electronic payment device via the second interface. The second interface may be a single TWI (Two-wire Interface) interface, and the electronic payment device can realize functions such as USB Key, OTP, and smart card. The present invention realizes converting data from a terminal into data suitable for communication with the data receiving end by performing data conversion via the first interface using the data transmitting end as a relay device. Thus, the conversion between different interfaces was realized, and the application range of the data transmission end of the present invention was expanded. When the data transmission end is a single relay device, the current transmission target data bit string is acquired via the first interface, and the current transmission is performed via the second interface by the data transmission method according to the present invention. The target data bit string may be transmitted. Of course, the transmitting end of the data according to the embodiment of the present invention uses the reception method described in the second embodiment described later to transmit X pieces of data in the receiving method described in the second embodiment described later via the second interface. A second data bit string corresponding to X-1 time intervals may be obtained by receiving a signal and by a numerical value corresponding to an individual time interval in the obtained S time intervals. According to a protocol supported by the first interface, the second data bit string is encoded to obtain the second data, and the second data is transmitted through the first interface. At this time, according to the interface type of the first interface, the second data bit string received by the supporting protocol is encoded. For example, the first interface may encode the second data bit string according to the USB protocol, audio protocol, serial port protocol, Bluetooth protocol, WiFi protocol, NFC protocol, etc. Get the data. Data conversion is performed via the first interface, and the data bit string generated in this embodiment is converted into data that can be supported by the universal interface protocol to realize conversion between different interfaces. The application range of the data transmission end of the embodiment was expanded.

  Step 104: Group the data bit strings so that each group of data has N bits.

In this embodiment, step 103 and step 104 may be performed at any timing before step 102. Before transmitting data, the data bit string may be acquired and grouped. Further, the data transmission end may execute step 101 and step 102 once before transmitting data every time. Alternatively, the data transmission end first executes step 101 and step 102, and thereafter, every time data is transmitted, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained by step 102. Then, the current transmission target data may be encoded. Alternatively, setting one expiration date and transmitting data within the expiration date may be obtained by acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval in step 102, It is also possible to employ encoding for the data to be transmitted. Alternatively, each time an event trigger is received by means of event trigger, for example, the user inputs a time parameter for transmitting the current data, and 2 ^N different values and times contained in the N-bit data The correspondence of intervals is calculated once. This embodiment is not specifically limited.

  As one selectable embodiment of the present invention, the data bit strings can be grouped in multiple ways so that each group of data is N bits. Grouping may be performed so that each group includes 1 bit, or grouping may be performed so that each group includes 2 bits. When the data bit string includes a singular number, grouping cannot be performed completely by a method including two bits. Therefore, the data bit string is supplemented with 0 and then grouped. At this time, the data transmission end and the data reception end are set or agreed in advance with respect to a method of supplementing 0. When transmitting a data bit string from the high order bits of data, the last bit of the bit string is supplemented with 0. Also, when transmitting a data bit string from the low order bits of data, 0 is supplemented to the high order bits of the bit string. Of course, when each group includes 3 bits and 3 bits or more, it is only necessary to refer to a method of grouping so that each group includes 2 bits.

  Step 105: Based on the acquired correspondence relationship, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group.

  In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of identical time intervals. For example, referring to FIG. 2, when data of one group includes 2 bits, the numerical value of the data of the group is 00, 01, 10 and 11, and the numerical value of the data of the group is 00, 1 The numerical value 00 is shown in one time interval, and at this time, the time length corresponding to the one time interval is etu. That is, the expression method of the data 00 of the group may be, for example, one time interval of 10 μs. When the data of the group is 00, a numerical value 00 may be indicated at five time intervals. At this time, the time length of each time interval in the five time intervals may be etu. That is, the expression method of the data 00 of the group may be a signal having five time intervals, and each time interval is a time interval of 10 μs. Employing the fact that the numerical value of each group of data corresponds to one time interval increases the data transmission speed and improves the efficiency. If it is adopted that the numerical values of the data of each group correspond to a plurality of time intervals, the numerical values corresponding to the time intervals can be accurately determined, and mistakes due to loss of the time intervals can be prevented during data transmission.

  In one selectable embodiment of the present embodiment, when data of each group is transmitted, M signals are generated and transmitted. Among them, the time interval of the start time of one signal adjacent to the start time of each signal is a time interval corresponding to the numerical value of the data of the group, M ≧ 1, and M is a natural number. The time interval generated by adopting the signal is easy to detect and has an effect of high stability.

  In addition, M signals may be generated by generating M low level pulses according to the time interval, or M signals may be generated by generating M high level pulses according to the time interval. Also good. The low level pulse / high level pulse may be a waveform that can distinguish the low level pulse / high level pulse by a rectangular wave, a sine wave, a triangular wave, or the like, but is not limited thereto. Preferably, a low level pulse is generated according to a time interval, and when the transmitting end and the receiving end communicate with each other, a method is adopted in which the transmitting end supplies power to the receiving end at a high level and transmits information with a low level pulse. A device adopting such a method can simultaneously perform power feeding and information transmission through the same line when performing information interaction, and thus the volume and cost of the device can be reduced.

  In one selectable embodiment of the present example, before transmitting the first group data of step 105, the method further includes a step 105a of generating and transmitting K handshake signals. However, K ≧ 2 and K is an integer. Since only one time interval can be formed between two adjacent signals, at least two handshake signals must be generated and transmitted to indicate that there is at least one time interval. The transmitting end transmits a handshake signal, and the receiving end determines the data transmission start position based on the handshake signal, thereby improving the data transmission efficiency.

  In addition, a preset relationship is satisfied among the K handshake signals. The transmitting end transmits a handshake signal that satisfies a preset relationship, and the receiving end can accurately determine whether or not the received data is a handshake signal based on the preset relationship.

  In addition, a time parameter is included in the handshake signal. The receiving end obtains a time parameter by the K handshake signals, so that when the receiving end receives a signal from the transmitting end, the receiving end obtains a time interval, and data from the transmitting end according to the time parameter and the time interval. To get. Thereby, the receiving end can acquire the time interval indicating the numerical value of the data according to the time parameter used at the transmitting end, and the problem that the theoretical time parameter of the receiving end does not match the actual time parameter is solved.

  In addition, the above-mentioned “satisfy a preset relationship between K handshake signals” means that a preset relationship is satisfied between the first time interval and the second time interval. There may be. Here, the first time interval is a time interval between the start time of the i-th handshake signal and the start time of the i-1th handshake signal, and the second time interval is the i-th handshake signal. Is the time interval between the start time of the first handshake signal and the start time of the (i + 1) th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3 and K is an odd number. In this selectable embodiment, “satisfying a preset relationship between the first time interval and the second time interval” is a relationship promised in advance by the transmitting end and the receiving end. For example, the second time interval is twice the first time interval. Whether the transmitting end transmits a handshake signal that satisfies a preset relationship, and whether the received signal is a handshake signal depending on whether the received data satisfies a preset relationship Judging. For example, when generating and transmitting five handshake signals, four time intervals t0, t1, t2, and t3 are included, where the first time interval includes t0 and t2, and the second time The interval may include t1 and t3. Further, the preset relationship in which the first time interval and the second time interval are satisfied may be t1 = 2t0 and t3 = 2t2.

  In addition, by transmitting the time parameter in step 101 according to the time interval between the K handshake signals described above, the receiving end can obtain the time parameter used for the transmitting end by the K handshake signals, The time parameter used at the receiving end can be further confirmed. Specifically, the transmitting end may determine the first time interval group and the second time interval group according to the time parameter in step 101, the first time interval group including at least one first time interval, The two time interval groups include at least one second time interval.

  In addition, K handshake signals are generated by generating K low level pulses at the first time interval and the second time interval. Alternatively, K handshake signals may be generated by generating K high-level pulses at the first time interval and the second time interval. As the low level pulse / high level pulse, a waveform capable of distinguishing the low level pulse / high level pulse from a rectangular wave, a sine wave, a triangular wave, or the like is shown, but the present invention is not limited thereto. Preferably, a handshake signal is generated by generating a low level pulse according to a time interval, and when the transmitting end and the receiving end communicate, the transmitting end feeds the receiving end at a high level and transmits information by a low level pulse. Adopt the method to do. A device adopting such a method can simultaneously perform power feeding and information transmission through the same line when performing information interaction, and thus the volume and cost of the device can be reduced.

  In one selectable embodiment of the present example, after step 105, the time parameter may be changed to satisfy the current rate of data transmission. That is, after step 105, in accordance with a preset rule, the currently used time parameter is switched to the new time parameter, the new time parameter is determined as the time parameter for transmitting the current data, and the current data is transmitted. The correspondence relationship may be updated according to the time parameter, and the data transmission may be further performed in the subsequent data transmission process based on the updated correspondence relationship. In this embodiment, the determination of the new time parameter may be completed through agreement between the transmitting end and the receiving end, or may be completed by querying a list of time parameters stored in advance by the transmitting end and the receiving end. Also good. For example, when sending a type of data, query the list to determine the time parameter that the type of data should use. The time parameter at the transmitting end is variable, and receiving ends with different data processing capabilities are matched, or different types of data are matched to further improve data processing efficiency.

  In one selectable embodiment of this embodiment, after completing the transmission of the last group of data in step 105, the verification data is transmitted, and the verification data is used to transmit the data received by the data receiving end. A step 106 of determining completeness and accuracy may further be included. The verification data is verification data calculated by a verification method such as MAC verification, parity verification, or sum verification, but is not limited thereto.

  In one selectable embodiment of the present example, after completing the transmission of the last group of data in step 105 or after completing the transmission of the last group of data in step 105, , Step 107 may further include a step 107 of transmitting A end signals (A ≧ 1 and an integer). The end signal may be the same as or different from the handshake signal. Based on the end signal, the receiving end can determine whether or not the reception of data has ended.

  According to the technical means provided by the above-described embodiment of the present invention, the transmission end can indicate the data of the transmission waveform at the time interval of the transmission waveform, and the transmission of data can be completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

  Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking an example that the current bit string to be transmitted is 0011100100 and N = 2.

  In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is a length of time occupied by data transmission. There is no correspondence between the number of time parameters and N, and it is only necessary to match the receiving end. The present embodiment is not limited to the specific number, as long as the time parameter can express the time interval corresponding to the numerical value of the data.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 2, the correspondence between four different numerical values included in the 2-bit data and the time interval is acquired according to the time parameter. That is, 00 = etu, 01 = etu + pdt, 10 = etu + 2 pdt, and 11 = etu + 3 pdt. In the present invention, a time interval corresponding to a numerical value of 2-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

  In step 103, the current data bit string 0011100100 to be transmitted is acquired.

  In step 104, the data bit string 0011100100 is grouped so that each group of data is 2 bits, that is, includes 00 11 10 01 00.

  In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals. For example, 00 corresponds to a time interval of one etu (for example, 10 μs), and after one signal, another signal is transmitted at the time interval. The time length of the etu formed in this way indicates the numerical value 00. Of course, 00 may correspond to three etu time intervals (for example, each time interval is 10 μs), and after one signal, three signals are continuously transmitted and received at the etu time interval. If the end receives three such same time lengths, it is determined that the value 00 has been received. When the data of each group is shown at a plurality of the same time intervals, the number of time intervals may be the same at the transmitting end and the receiving end, but this embodiment is not specifically limited thereto.

  In the present embodiment, the numerical value 00 is transmitted at the time interval of etu according to the order of the data bit strings. Indicates that the numerical value 11 is transmitted at the time interval of etu + 3 pdt, indicates that the numerical value 10 is transmitted at the time interval of etu + 2 pdt, indicates that the numerical value 01 is transmitted at the time interval of etu + pdt, and indicates the numerical value 00 at the time interval of etu. Indicates sending. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 3 as an example of one time interval corresponding to the numerical value of each group of data. The transmission of the data bit string is performed at the time interval between the signals. Complete.

  Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking as an example that the current bit string to be transmitted is 0011100100 and N = 1.

  In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. Since there is no correspondence between the number of time parameters and N, the present embodiment only needs to be able to express a time interval in which the time parameter corresponds to the numerical value of the data. Therefore, the number of time parameters is limited to a specific number of time parameters. do not do.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 1, the correspondence between two different numerical values included in 1-bit data and the time interval is acquired according to the time parameter. That is, 0 = etu and 1 = pdt may be used. In the present invention, a time interval corresponding to a numerical value of 1-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

  In step 103, the current data bit string 0011100100 to be transmitted is acquired.

  In step 104, the data bit string 0011100100 is grouped so that each group of data includes 1 bit, that is, 0 0 1 1 1 0 0 1 0 0, but this step may be omitted. .

  In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In this embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals. For example, 0 corresponds to one etu time interval (for example, 10 μs), and after one signal, another one signal is transmitted at the time interval. The time length of the etu formed in this way shows the numerical value 0. Of course, 0 may correspond to three etu time intervals (for example, each time interval is 10 μs), and after one signal, three signals are continuously transmitted and received at the etu time interval. When the same three time lengths are received at the end, it is determined that the numerical value 0 is received.

  In this embodiment, data of each group is transmitted according to the order of data bit strings. That is, the time interval of each signal is the time interval of etu, the time interval of etu, the time interval of pdt, the time interval of pdt, the time interval of pdt, the time interval of etu, the time interval of etu, the time interval of pdt, Time interval, etu time interval. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 4 by taking one time interval corresponding to the numerical value of the data of each group as an example, but the transmission of the data bit string is performed at the time interval between the signals. Complete.

  Hereinafter, the data transmission method provided by the embodiment of the present invention will be briefly described by taking as an example that the current bit string to be transmitted is 0011100100 and N = 3.

  In step 101, the current transmission time parameter is determined. In addition, two time parameters, that is, a first time parameter etu and a second time parameter pdt are determined. Here, etu = 10 μs and pdt = 30 μs. Since there is no correspondence between the number of time parameters and N, the present embodiment only needs to be able to express a time interval in which the time parameter corresponds to the numerical value of the data. Therefore, the number of time parameters is limited to a specific number of time parameters. do not do.

In step 102, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is obtained according to the time parameter. For example, when N = 3, the correspondence between eight different numerical values included in the 3-bit data and the time interval is acquired by the time parameter. For example, 000 = etu, 001 = etu + pdt, 010 = etu + 2 pdt, 011 = etu + 3 pdt, 100 = etu + 4 pdt, 101 = etu + 5 pdt, 110 = etu + 6 pdt, 111 = etu + 7 pdt. In the present invention, a time interval corresponding to a numerical value of 3-bit data can be expressed by a plurality of combinations of time parameters, but the present invention is not limited thereto.

  In step 103, the current data bit string 0011100100 to be transmitted is acquired.

  In step 104, the data bit string 0011100100 is grouped so that each group of data is 3 bits. In this embodiment, when the acquired data bit string is not an integer multiple of the number of bits included in each group, an operation of supplementing 0 to the data bit string is performed. When the transmission order of the data bit string is changed from low-bid to high-order bit, the high-bit is supplemented with 0 to perform grouping to become 000 011 100 100, and the transmission order of the data bit string is changed from high-order bit to low-order bit Then, 0 is added to the low-order bits and grouping is performed to obtain 001 110 010 000.

  In step 105, based on the acquired correspondence, the data of the group is transmitted so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group. In the present embodiment, the numerical value of the data of each group may correspond to one time interval or may correspond to a plurality of the same time intervals.

  In this embodiment, the data of each group is transmitted in the order from the low order bit to the high order bit of the data bit string. In other words, a signal having a time interval of etu + 4 pdt, a signal having a time interval of etu + 4 pdt, a signal having a time interval of etu + 3 pdt, and a signal having a time interval of etu are transmitted. The waveform for transmitting the data bit string 0011100100 is shown in FIG. 5 by taking one time interval corresponding to the numerical value of the data of each group as an example, but the transmission of the data bit string is performed at the time interval between the signals. Complete. Of course, when data of each group is transmitted in the order from the high-order bit to the low-order bit, 0 may be supplemented to the low-order bit. The data transmission method is similar to the order from the low order bit to the high order bit. Since signals need only be sequentially transmitted according to a time interval corresponding to a numerical value starting from the high-order bit, it will not be described in detail here.

  When N ≧ 4, data may be transmitted with reference to the data transmission method when N = 2 or N = 3.

  When N = 1.5, data may be transmitted with reference to the data transmission method when N = 2, but there are differences as follows.

  Corresponds to a numerical value in 3-bit data using at least two time intervals. That is, when the value of N is a non-integer, a plurality of time intervals are used to correspond to different numerical values in the B bit data. However, B is an integer multiple of N, and B is a positive integer.

Example 2
The present embodiment provides a data receiving method, and FIG. 6 is a flowchart of one selectable data receiving method of the present embodiment. The execution subject of the embodiment of the present invention may be a receiving end that receives data.

  As shown in FIG. 6, the data receiving method mainly includes the following steps 201 to 203.

  Step 201: Determine a time parameter for transmitting current data.

  In one selectable embodiment of the present embodiment, the time parameter for transmitting the current data may be set and determined in advance at the data receiving end. Further, the data receiving end may be determined by obtaining from the transmitting end. Furthermore, the data receiving end may be calculated and determined by setting in advance. For example, the receiving end first receives a handshake signal before receiving data, and determines a time parameter for transmitting current data according to the handshake signal. It is not limited to the parameter determination method. Finally, any method that can determine the time parameter for transmitting the current data belongs to the protection scope of the present invention.

  In one selectable embodiment of the present example, this step is a selectable step.

  Step 202, receive X signals, determine a time interval between the start times of two adjacent signals in the X signals, and obtain X-1 time intervals. However, X is a positive integer and X> 1.

  In one selectable embodiment of the present example, “receive X signals” may detect X low level pulses or X high level pulses. . As the low level pulse / high level pulse, a waveform capable of distinguishing the low level pulse / high level pulse from a rectangular wave, a sine wave, a triangular wave, or the like is shown, but the present invention is not limited thereto. Preferably, a low level pulse is detected. That is, when the transmitting end can provide a high level to the receiving end, a low level pulse is generated. When the transmitting end and the receiving end communicate with each other by such a method, the receiving end uses the high level from the transmitting end as a power source. The electric energy is provided to the electricity consuming member at the receiving end. For example, the receiving end is charged by a high level from the transmitting end, or a power source is not provided inside the receiving end, and the high level from the transmitting end is directly used as a power source. When a device adopting such a method performs information interaction, it can simultaneously perform power feeding and information reception through the same line, thereby reducing the volume and cost of the device.

  In one selectable embodiment of the present example, prior to step 202, step 202a receives K signals and detects whether or not a predetermined relationship is satisfied between the K signals. Further included. However, K ≧ 2 and K is an integer. Since one time interval is formed only between two adjacent signals, at least two handshake signals should be received to obtain at least one time interval. The receiving end determines whether or not the K signals are handshake signals based on whether or not a predetermined relationship between the K signals is satisfied. The receiving end receives the handshake signal, determines the data transmission start position based on the handshake signal, and improves the data transmission efficiency.

  In addition, in step 202a, a time interval between the K signals is detected, and it is determined whether or not the first time interval and the second time interval satisfy a preset relationship. Here, the first time interval is a time interval between the start time of the i-th signal and the start time of the (i-1) -th signal, and the second time interval is the start of the i-th signal. Time interval between the time and the start time of the (i + 1) th signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number . When the first time interval and the second time interval satisfy a preset relationship, a step of receiving X signals is executed. That is, it is determined that the received K signals are handshake signals, and the signals after the K signals are data transmission signals. Here, the value of K is provided in advance. Further, if the first time interval and the second time interval do not satisfy the preset relationship, the time interval between the subsequent K signals is detected, and the K number of times satisfying the preset relationship are detected. Before detecting a signal, it is determined whether or not a predetermined relationship is satisfied between the first time interval and the second time interval of the subsequent K signals. That is, when the handshake signal is not detected, the receiving end continues to detect the handshake signal and starts receiving data after detecting the handshake signal. As a result, it is possible to prevent a signal from being transmitted to the receiving end when there is an error operation at the transmitting end, and at the same time, it is possible to determine the start of data. Further, the preset relationship that satisfies the interval between the first time interval and the second time interval may be a relationship that the transmitting end and the receiving end promise in advance. For example, the second time interval is twice the first time interval. The receiving end determines whether or not the received signal is a handshake signal depending on whether or not the received data satisfies a preset relationship. For example, if five signals are received, it includes four time intervals t0, t1, t2 and t3, where the first time interval includes t0 and t2, and the second time interval includes t1 and t3. May be included. Further, the preset relationship in which the first time interval and the second time interval are satisfied may be t1 = 2t0 and t3 = 2t2.

  Further, in step 202a, the received K signals further include a time parameter, and in step 201, the time parameter can be determined by the K signals. In addition, the first time interval group and the second time interval group are first determined, wherein the first time interval group includes at least one first time interval, and the second time interval group is at least One second time interval is included. Then, the time parameter is determined by the first time interval group and the second time interval group. For example, if the transmitting end transmits five handshake signals, and the first time interval t1 = etu and the second time interval t2 = etu + pdt, the receiving end depends on the first time interval and the second time interval. The values of the time parameters etu and pdt can be determined. By determining the time parameter based on the K signals, it is possible to prevent the theoretical time parameter at the receiving end from matching with the actual time parameter, and to ensure the accuracy of data transmission.

  Similar to a signal transmitting data, the receiving end can detect that K signals have been received by detecting K low level pulses. Alternatively, K high-level pulses can be detected to determine that K signals have been received. The low level / high level pulse can be realized by a rectangular wave, a sine wave, or the like. Preferably, when a low level pulse is detected, that is, when the transmitting end provides a high level to the receiving end and K signals need to be transmitted, K low level pulses are generated to generate a transmitting end. When the receiving end communicates, a method is adopted in which the receiving end uses the high level from the transmitting end as a power source, or directly uses the high level of the transmitting end as a power source without providing a power source inside the receiving end. When a device using such a method performs information interaction, it can simultaneously perform power supply and information reception via the same line. Therefore, when performing information interaction that can reduce the volume and cost of the device, the device is connected via the same line. Thus, power supply and information reception can be performed simultaneously, so that the volume and cost of the device can be reduced.

  The above description may refer to any one of Examples 14 to 17 regarding a specific mode in which K signals are received and a time parameter is acquired.

  In one selectable embodiment of this example, receiving X signals means receiving Y + 1 signals, removing noise in Y + 1 signals, and obtaining X signals. Including. However, Y + 1 ≧ X. Specifically, any one of Examples 10 to 13 may be referred to.

According to the time parameter for transmitting the current data determined in step 203 and step 201, a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, The numerical values transmitted in S time intervals are acquired, and the numerical values transmitted in S time intervals are numerical values corresponding to individual time intervals, and the numerical values are 2 ^N different numerical values included in N-bit data. Where S> 1, S time intervals are the same, X and S are both positive integers, and S ≦ X−1, N ≧ 1 . When S> 1 in X−1 time intervals, S consecutive time intervals are the same, and the value of N-bit data corresponding to each individual time interval is the number of S A numerical value transmitted in a time interval. For example, if seven signals are received, six time intervals are acquired, and three consecutive time intervals therein are the same. That is, the transmitting end indicates the numerical value of N-bit data at a plurality of the same time intervals, acquires N-bit data corresponding to individual time intervals among the three time intervals, and further transmits the N-bit data at three time intervals. A numerical value is acquired, and when S = 1, a numerical value transmitted in one time interval is acquired.

  As an optional embodiment of an embodiment of the present invention, an individual for every successive S time intervals in X-1 time intervals, depending on the time parameter for transmitting the current data determined in step 201. A numerical value corresponding to each time interval is acquired, numerical values transmitted in S time intervals are acquired, and numerical values corresponding to individual time intervals are calculated and acquired by a plurality of calculation methods. For example, a numerical value corresponding to the time interval is obtained by a time interval of numerical value m = etu + m * pdt, which is a preset or agreed calculation method. For example, one time interval is received, and the numerical value of m is calculated and acquired by etu and pdt. For example, when m = 1, if the data of each group set or agreed in advance is 1 bit, the numerical value is 1, and if the data of each group is 2 bits, the numerical value is 01. If the data of each group is 3 bits, the numerical value is 001, and if the data of each group is 4 bits or 4 bits or more, the method of obtaining the numerical value is the same, and will be described in detail here. do not do.

According to one possible embodiment of an embodiment of the present invention, an individual time interval for each successive S time intervals in X-1 time intervals, depending on the time parameter for transmitting the determined current data. To obtain a numerical value transmitted in S time intervals (the numerical value is one of 2 ^N different numerical values included in the N-bit data, where S> 1 , S time intervals are the same, X and S are both positive integers, and S ≦ X−1, N ≧ 1) can be understood as follows.

  According to the determined time parameter for transmitting the current data, a bit string corresponding to an individual time interval for each successive S time intervals in X-1 time intervals is obtained, and S time intervals are obtained. Get the bit string transmitted in. Here, if the numerical values transmitted in S time intervals are bit strings corresponding to individual time intervals, and S> 1, the S time intervals are the same, and S is a positive integer. And S ≦ X−1. For example, when X = 2 and S = 1, there is only one time interval, and a bit string corresponding to the time interval is acquired. When X is 3 or 3 and S = 1, a bit string having a plurality of time intervals and corresponding to each time interval is obtained. If X = 3 and S = 2, then there are two time intervals, the two time intervals are the same, and the time interval corresponds to one bit string, and the two time intervals are A bit string corresponding to one time interval is shown. If X is 5 or greater and 5 and S = 2, then it has 4 time intervals, one time interval in the previous two consecutive time intervals corresponds to one bit string, and later One time interval in two consecutive time intervals corresponds to one other bit string. That is, the previous two time intervals indicate one bit string, and the latter two time intervals indicate another bit string. Of course, the examples given above are exemplary, and any method capable of obtaining a bit string transmitted in S time intervals belongs to the protection scope of the present invention.

In one selectable embodiment of this example, before obtaining the numerical value transmitted in the first consecutive S time intervals in X-1 time intervals in step 203, the time parameter , Further includes a step 203 ′ of acquiring correspondence between 2 ^N different numerical values included in the N-bit data and time intervals. Here, the time intervals corresponding to different numerical values are different, and N ≧ 1. By determining a numerical value corresponding to the received time interval by calculating in advance 2 ^N different numerical values and time intervals included in the N-bit data, the decoding time after receiving the data can be further reduced. As one selectable embodiment of the embodiment of the present invention, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter (where time corresponding to the different numerical values is obtained). The interval is different and N ≧ 1) can be understood as follows. By the time parameter, 2 ^N pieces of length to obtain the corresponding relationship between the bit strings and time intervals in the bit string is N (where, 2 ^N bits string different from each other and corresponding to the different bit strings Time interval to be different and N ≧ 1).

In one selectable embodiment of the present embodiment, the embodiment does not include step 201. In this embodiment, “2 ^N different numerical values included in N-bit data and the correspondence relationship between time intervals are acquired. , Where the time intervals corresponding to different numbers are different ”is an essential step, i.e., if no time parameter determining the current data transmission is included, 2 ^N different numbers included in the N-bit data The correspondence between time intervals must be included.

In one selectable embodiment of the present embodiment, “2 ^N different numerical values included in N-bit data” can be understood as follows. For example, if the N = 1, comprises 2 to ¹ different numbers to 1-bit data is 0 and 1, respectively. If it is N = 2, it comprises ^{two two} different numbers within 2-bit data, respectively 00, 01, 10 and 11. “According to the time parameter, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired” can be understood as follows. For example, when N = 1, the time interval corresponding to 0 is acquired by the time parameter, and the time interval corresponding to 1 is acquired by the time parameter. When N = 2, the time interval corresponding to 00 is acquired by the time parameter, the time interval corresponding to 01 is acquired by the time parameter, the time interval corresponding to 10 is acquired by the time parameter, and the time The time interval corresponding to 11 is acquired by the parameter. Of course, when N is another value, it can be understood in the same manner as described above, so it will not be described in detail here.

In addition, the data receiving end calculates a time interval corresponding to the numerical value of the data by a calculation method set or agreed in advance with the data transmitting end. N = n, and the calculation method of the time interval corresponding to the numerical value m is the time interval corresponding to the numerical value m = etu + m * pdt (where 0 ≦ m ≦ 2 ⁿ −1, etu is the first time parameter) , Pdt is the second time parameter (for example, etu = 10 μs, pdt = 30 μs), ie, the time interval calculation method corresponding to the numerical value 11 is 10 μs + 3 * 30 μs = 100 μs, and this selectable implementation Depending on the form, the time interval corresponding to the numerical value can be calculated. Of course, the present invention may determine the time interval by other pre-agreed calculation methods. The present embodiment is not specifically limited to this. If the time interval corresponding to the numerical value is calculated by a calculation method agreed in advance, the expandability of data transmission can be ensured. That is, regardless of what the value of N is, the time interval corresponding to the numerical value of each data can be calculated at the transmitting end and the receiving end. The receiving end compares the calculated time interval with the received time interval, and can directly determine a numerical value corresponding to the time interval, thereby improving the efficiency of determining data.

  As another selectable embodiment of the embodiment of the present invention, the data receiving end can determine the time interval corresponding to the numerical value by a list stored in advance by agreement with the data transmitting end. If the time interval corresponding to the numerical value is determined by the method of querying the list, the efficiency of obtaining the time interval corresponding to the numerical value can be improved.

  In one selectable embodiment of this example, X−1 = n * S, n ≧ 1, and n is an integer. According to such a selectable embodiment, X signals can just transmit n * S data, and no problem arises that cannot be decoded by extra signals.

In one selectable embodiment of the present example, the time parameter can also be updated during data transmission. That is, after step 203, according to a preset rule, the currently used time parameter is replaced with a new time parameter, the new time parameter is determined as the time parameter for transmitting the current data, and X signals are received. Determine the time interval between the start times of two adjacent signals in X signals, obtain X-1 time intervals, and use the time parameter to transmit the current data Obtaining a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals, obtaining a numerical value transmitted in S time intervals, and is a numerical value numerical values transmitted corresponds to each time interval in the time interval, the number is the one in ^the 2 ^N different numbers within N-bit data, when the S> 1, S number of time intervals Further comprising the step 204 each time interval the definitive are identical. In this embodiment, the determination of a new time parameter may be completed by agreement between the transmitting end and the receiving end, or may be completed by querying a list of time parameters stored in advance by the transmitting end and the receiving end. Also good. For example, when sending a type of data, the list is queried to determine the time parameter that the type of data should use. The time parameter of the transmitting end is variable, and it can be matched with a receiving end having different data processing capabilities or different types of data, thereby further improving the efficiency of data processing.

  In one selectable embodiment of the present example, after completing the reception of the last one data in step 203, the transmitting end transmits A end signals (A ≧ 1 and an integer). The receiving end can also receive A end signals. The end signal may be the same as the handshake signal or may be a signal in another specific format. The receiving end determines whether or not the reception of data is completed based on the end signal.

  In one selectable embodiment of the present embodiment, after completion of reception of the last data in step 203 or after completion of reception of the last data, A end signals Before receiving the data, the receiving end can receive the verification data transmitted from the transmitting end, and the receiving end of the data determines whether the received data is complete and accurate based on the verification data. The verification data includes verification data calculated by a check method such as MAC verification, parity verification, or sum verification.

  According to the technical means provided by the above-described embodiment of the present invention, the receiving end can determine the numerical value of the data of the received waveform according to the time interval of the received waveform, and can complete the data reception using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

  As one selectable embodiment of the present invention, the data receiving end may be a single relay device that relays communication between the data transmitting end and another device (hereinafter referred to as the first terminal). . At this time, the data receiving end receives X signals through the second interface by the receiving method according to the present embodiment, and corresponds to the individual time intervals by the acquired S time intervals. To obtain a second data bit string corresponding to X-1 time intervals, and to encode the second data bit string according to a protocol supported by the first interface. The second data may be acquired and the second data may be transmitted via the first interface. At this time, according to the interface type of the first interface, the second data bit string received by the supporting protocol is encoded. For example, the first interface encodes the second data bit string according to the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, the NFC protocol, etc., and the second data to be transmitted now. To get. Data conversion is performed via the first interface, the data bit string generated in the present embodiment is converted into data that can be supported by the universal interface protocol, and conversion between different interfaces is realized. The application range of the receiving end of the example data has been expanded. Of course, when the data receiving end of the present invention is a relay device, it is also possible to receive the first data via the first interface, and the first data can be received by a protocol supported by the first interface. To obtain the first data bit string of the current transmission target, and after acquiring the data bit string of the current transmission target through the first interface, the first embodiment of the present invention The data bit string to be currently transmitted may be transmitted via the second interface by the data transmission method provided by the above. Further, when the data receiving end is a relay device, the data receiving end may have two communication interfaces. For example, the interface includes a first interface and a second interface, the first interface is an interface that communicates with the first terminal, and the second interface is an interface that communicates with a data transmission end. The first interface may be a conventional universal interface such as a wireless interface such as a USB interface, an audio interface, a serial port, Bluetooth, WiFi, or NFC, or a wired interface. You may connect to a 1st terminal via the said 1st interface, and may transmit 2nd data to a 1st terminal. The first terminal may be a device such as a mobile phone, a computer, or a PAD, and the second data may be data received by the mobile phone, the computer, or the PAD. At the same time, the received first data is decoded by the supporting protocol according to the interface type of the first interface. For example, the first interface decodes the first data according to the USB protocol, the audio protocol, the serial port protocol, the Bluetooth protocol, the WiFi protocol, or the NFC protocol, and the data bit corresponding to the first data. The string may be acquired and transmitted via the second interface by the transmission method described in the first embodiment. The second interface may be an interface connected to an electronic payment device (ie, a data receiving end). Data may be transmitted to the electronic payment device via the second interface, and data transmitted from the electronic payment device via the second interface may be received. The second interface may be one TWI interface. The electronic payment device can realize functions such as USB Key, OTP, and smart card. Using the data reception end of the present invention as a relay device, data conversion can be performed via the first interface, and data from the data transmission end can be converted into data suitable for communication with the terminal.

  Hereinafter, the data reception method provided by the embodiment of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 2.

  In step 201, a time parameter for transmitting current data is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is the length of time occupied by data transmission. The number of time parameters does not have a corresponding relationship with N, and may simply be agreed upon with the transmitting end. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

  In step 202, six signals are received and the time intervals between the start times of two adjacent signals in the six signals are determined to obtain five time intervals of etu, etu + 3pdt, etu + 2pdt, etu + pdt, etu. To do.

In step 203, 2-bit data corresponding to each of the above five time intervals is acquired. In the present embodiment, a numerical value corresponding to the time interval is acquired by a calculation method m = etu + m * pdt agreed in advance with the data transmission end. For example, if one time interval of 100 μs is acquired, m = 3 can be acquired. That is, the numerical value transmitted at the time interval is 11. Also, before this step, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter. For example, when N = 2, the correspondence between four different numerical values included in the 2-bit data and the time interval is acquired according to the time parameter. That is, 00 = etu, 01 = etu + pdt, 10 = etu + 2 pdt, and 11 = etu + 3 pdt are acquired. For example, when a time interval of 100 μs is received, it can be directly determined that the numerical value transmitted in the time interval is 11. Finally, reception of the bit string 0011100100 is completed.

  In the present embodiment, the receiving end can indicate one group of data at one time interval in accordance with the transmission countermeasures at the transmitting end. For example, 00 is indicated at the time interval of only one etu, and the data transmission speed is increased. In addition, one group of data can be shown at a plurality of the same time intervals. For example, it indicates 00 at the time interval of three times of etu, so that the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

  Hereinafter, the data reception method of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 1.

  In step 201, a time parameter for transmitting current data is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. The number of time parameters has no correspondence with N. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

  In step 202, 11 signals are received, and time intervals between the start times of two adjacent signals in the 11 signals are determined, and etu, etu, pdt, pdt, pdt, etu, etu, Ten time intervals of pdt, etu, etu are acquired.

  In step 203, 1-bit data corresponding to each of the 10 time intervals described above is acquired, a numerical value 0 transmitted in the time interval of etu is acquired, a numerical value 0 transmitted in the time interval of etu is acquired, The numerical value 1 transmitted at the time interval of pdt is acquired, the numerical value 1 transmitted at the time interval of pdt is acquired,..., the numerical value 0 transmitted at the time interval of etu is acquired, and finally the bit string 0011100100 reception is completed.

  In this embodiment, according to the transmission countermeasures at the transmission end, the reception end can indicate 1-bit data at one time interval. For example, 00 is indicated at the time interval of only one etu, and the data transmission speed is increased. In addition, 1-bit data can be indicated at a plurality of the same time intervals. For example, it indicates 00 at the time interval of three times of etu, so that the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

  Hereinafter, the data reception method provided by the embodiment of the present invention will be briefly described by taking as an example that the bit string waiting for reception is 0011100100 and N = 3.

  In step 201, the time parameter of the current transmission is determined. In addition, the first time parameter etu and the second time parameter pdt which are two time parameters are determined. Here, etu = 10 μs and pdt = 30 μs. In an embodiment of the present invention, the time parameter is the length of time occupied by data transmission. The number of time parameters does not have a corresponding relationship with N, and may simply be agreed upon with the transmitting end. The present embodiment is not limited to the specific number of time parameters, as long as the time interval corresponding to the numerical value of the data can be expressed.

  In step 202, five signals are received, a time interval between the start times of two adjacent signals in the five signals is determined, and four time intervals of etu, etu + 3 pdt, etu + 4 pdt, etu + 4 pdt are obtained.

In step 203, 2-bit data corresponding to the four time intervals described above is acquired. In this embodiment, a numerical value corresponding to the time interval is obtained by a calculation method m = etu + m * pd agreed in advance with the data transmission end. For example, if one time interval of 100 μs is acquired, m = 3 can be acquired. That is, the data of the group is 101. Also, before this step, the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval is acquired by the time parameter. For example, when N = 3, the correspondence between eight different numerical values included in the 3-bit data and the time interval is acquired by the time parameter. That is, 000 = etu, 001 = etu + pdt, 010 = etu + 2 pdt, 011 = etu + 3 pdt, 100 = etu + 4 pdt, 101 = etu + 5 pdt, 110 = etu + 6 pdt, 111 = etu + 7 pdt. For example, when a time interval of 100 μs is received, it can be directly determined that the numerical value of the data is 101. Finally, bits supplemented with 0 are deleted according to the number of data bits agreed in advance with the data transmission end, and reception of the bit string 0011100100 is completed.

  In the present embodiment, the receiving end can indicate one group of data at one time interval in accordance with the transmission countermeasures at the transmitting end. For example, 000 is indicated at a time interval of one-time etu, and the data transmission speed is increased. In addition, one group of data can be shown at a plurality of the same time intervals. For example, 000 is indicated in the time interval of three times of etu, and the accuracy of data transmission is high, and a determination error due to loss of the time interval can be prevented.

  When N ≧ 4, the data can be received with reference to the data receiving method when N = 2 or N = 3, and will not be described in detail here.

Example 3
The present embodiment provides a data transmission apparatus. Since the apparatus corresponds to the data transmission method according to the first embodiment, it will not be described in detail, but will be described briefly here. For parts where the explanation is not clear, the first embodiment may be referred to.

  In the present embodiment, the data transmission device may be a device such as a mobile phone, a computer, or a POS register.

  FIG. 7 is a schematic diagram illustrating the configuration of one selectable data transmission apparatus according to the present embodiment. The apparatus mainly includes a time parameter determination unit 301, a time interval acquisition unit 302, a data bit string acquisition unit 303, and a transmission unit 304.

In this embodiment, the time parameter determination unit 301 is for determining a time parameter for transmitting current data. The time interval acquisition unit 302 is for acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval depending on the time parameter, and here, the time intervals corresponding to the different numerical values are different. N ≧ 1. The data bit string acquisition unit 303 is for acquiring a current data bit string to be transmitted and performing grouping on the data bit string so that each group of data has N bits. The transmission unit 304 is for transmitting the data of the group so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group based on the acquired correspondence.

  In one selectable embodiment of the present invention, the transmission unit 304 transmitting the group data for each group of data includes the transmission unit 304 generating and transmitting M signals. . Here, the time interval between the start time of each signal and the start time of one adjacent signal is a time interval corresponding to the numerical value of the data in the group, M ≧ 1, and M is a natural number.

  As one selectable embodiment of the present invention, the generation of M signals by the transmission unit 304 includes the transmission unit 304 generating M low level pulses over time intervals.

  As one selectable embodiment of the invention, the data transmission device further comprises a handshake signal transmission unit 305 for generating and transmitting K handshake signals, where K ≧ 2 and K Is an integer.

  In one selectable embodiment of the present invention, a preset relationship between the K handshake signals is satisfied.

  In one selectable embodiment of the present invention, the K handshake signals include time parameters.

  As one selectable embodiment of the present invention, satisfying the preset relationship between the K handshake signals is preset between the first time interval and the second time interval. Satisfying the relationship, wherein the first time interval is a time interval between the start time of the i th handshake signal and the start time of the i−1 handshake signal, and the second time The interval is a time interval between the start time of the i-th handshake signal and the start time of the (i + 1) -th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number.

  As one selectable embodiment of the present invention, the data transmission device further comprises a handshake signal time interval determination unit 306 for determining the first time interval group and / or the second time interval group according to the time parameter. The first time interval group includes at least one first time interval, and the second time interval group includes at least one second time interval.

  As one selectable embodiment of the present invention, the generation of K handshake signals by the handshake signal transmission unit 305 is performed K times by the handshake signal transmission unit 305 according to the first time interval and the second time interval. Generating a low level pulse.

  As one selectable embodiment of the present invention, the data transmission device replaces the currently used time parameter with a new time parameter according to a preset rule, and the new time parameter transmits the current data. And a time parameter update unit 307 for triggering the time interval acquisition unit 302 to update the correspondence with the new time parameter, and a time interval for updating the correspondence with the time parameter for transmitting the current data It further includes an acquisition unit 302 and a transmission unit 304 for performing data transmission based on the updated correspondence.

  According to the technical means provided by the above-described embodiment of the present invention, the data transmission apparatus can indicate the data of the transmission waveform at the time interval of the transmission waveform, and the transmission of the data is completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

Example 4
The present embodiment provides a data receiving apparatus. Since the apparatus corresponds to the data receiving method according to the second embodiment, it will not be described in detail, but will be described briefly here. For parts where the explanation is not clear, the second embodiment may be referred to.

  In this embodiment, the data receiving device may be an electronic payment device having device functions such as a smart card, a smart key device, and a dynamic password, and is used in combination with the data transmitting device in the third embodiment.

  FIG. 8 is a schematic diagram showing a configuration of one selectable data receiving apparatus according to the present embodiment. The apparatus includes a time parameter determination unit 401, a reception unit 403, and a data acquisition unit 404.

In this embodiment, the time parameter determination unit 401 is for determining a time parameter for transmitting current data. The receiving unit 403 receives X signals, determines a time interval between the start times of two adjacent signals in the X signals, and acquires X-1 time intervals. Yes, where X is a positive integer and X> 1. The data acquisition unit 404 acquires a numerical value corresponding to an individual time interval for each successive S time intervals in the X−1 time intervals based on the determined time parameter, The numerical value transmitted in the interval is obtained, the numerical value transmitted in the S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is included in 2 ^N pieces of data included in the N-bit data. It is one of the different numerical values. Here, when S> 1, each time interval in the S time intervals is the same.

In one selectable embodiment of the present invention, the data receiving device is for the data acquisition unit to acquire a numerical value transmitted in the first consecutive S time intervals in X-1 time intervals. In addition, a time interval acquisition unit 402 is further included for acquiring the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval according to the time parameter. Here, the time intervals corresponding to different numerical values are different.

  In one selectable embodiment of the invention, X-1 = n * S, n ≧ 1, and n is an integer.

  In one selectable embodiment of the present invention, receiving unit 403 receiving X signals includes detecting unit 403 detecting X low level pulses.

  In one selectable embodiment of the present invention, the data receiving apparatus receives K signals and detects whether or not the K signals satisfy a preset relationship. A signal receiving unit 405 is further provided.

  In one selectable embodiment of the invention, determining the time parameter for which the time parameter determining unit 401 transmits the current data means that the time parameter determining unit 401 determines the time parameter according to K signals. Including.

  In one selectable embodiment of the present invention, when the handshake signal receiving unit 405 receives the K signals, the handshake signal receiving unit 405 detects the time interval between the K signals, It is determined whether or not a predetermined relationship is satisfied between the first time interval and the second time interval, and the first time interval corresponds to the start time of the i th signal and the (i−1) th time. And the second time interval is the time interval between the start time of the i-th signal and the start time of the (i + 1) -th signal, and i = 2,4. ,..., 2j, j = (K-1) / 2, K ≧ 3, and K is an odd number, and a predetermined relationship is satisfied between the first time interval and the second time interval , Notifying the receiving unit to perform the step of receiving X signals.

  In one selectable embodiment of the present invention, the time parameter determination unit 401 determines the time parameter for transmitting the current data so that the time parameter determination unit 401 can use the first time interval group and / or the second time. Determining an interval group, wherein the first time interval group includes at least one first time interval, the second time interval group includes at least one second time interval, and the first time interval group and / or Or determining a time parameter by a second time interval group.

  In one selectable embodiment of the present invention, the handshake signal receiving unit 405 receiving the K signals includes the handshake signal receiving unit detecting K low level pulses.

In one selectable embodiment of the invention, according to a preset rule, the time parameter currently in use is replaced by a new time parameter, and the new time parameter is determined as the time parameter for transmitting the current data. Time parameter update unit 406 and X signals are received, and a time interval between the start times of two adjacent signals in X signals is determined to obtain X-1 time intervals. X-1 time, depending on the receiving unit for which X is a positive integer and X> 1, and the time parameter for transmitting the current data obtained by the time parameter update unit. Obtaining a numerical value corresponding to an individual time interval for each successive S time intervals in the interval, and obtaining a numerical value transmitted in S time intervals Tokusuru A data acquisition unit is a numerical value numerical value transmitted in the S time intervals corresponding to each time interval, the number is the one in ^the 2 ^N different numbers within N-bit data, wherein In the case of S> 1, it further includes a data acquisition unit in which each time interval in the S time intervals is the same.

  In one selectable embodiment of the invention, the data receiving device receives Y + 1 signals, removes noise in the Y + 1 signals, acquires X signals and transmits them to the receiving unit. A filtering unit 407, where Y + 1 ≧ X.

  According to the technical means provided by the above-described embodiment of the present invention, the data receiving apparatus can indicate the data of the received waveform at the time interval of the received waveform, and the reception of the data is completed using only two lines. When applied to an electronic device, the volume of the electronic device can be effectively reduced.

  Any process or method described in the flowcharts or described herein by other aspects is a module of code of executable instructions, one or more steps that includes steps for implementing one or more specific logic functions or processes. And the scope of the preferred embodiment of the present invention includes other implementations, where the order shown or described may not be followed, and the functions involved are essentially simultaneous. Or the functions may be performed in the reverse order. This should be understood by those skilled in the art to which the embodiments of the present invention belong.

  Each part of the present invention may be realized by hardware, software, firmware, or a combination thereof. In the embodiments described above, the steps or methods may be implemented by software or firmware that is stored in a memory and that executes the system with appropriate instructions. For example, when implemented by hardware, as in the other embodiments, for example, a discrete logic circuit having a logic gate circuit for realizing a logic function for a data signal, and a dedicated integration having an appropriate combinational logic gate circuit It may be realized by any one of the well-known techniques in the art such as a circuit, a programmable gate array (PGA), a field programmable gate array (FPGA), or a combination thereof.

  A person skilled in the art can complete the implementation of all or some of the steps included in the methods in the above embodiments by commanding the correlating hardware by a program, which is stored on a computer readable storage medium. Alternatively, when the program is executed, one step or combination of steps in the method embodiments is executed.

  Furthermore, each functional unit in each embodiment of the present invention may be integrated in one processing module. Each unit may be physically present individually. Two or more units may be integrated in one module. The integrated modules described above may be realized by hardware or may be realized by software function modules. If the integrated module is implemented in the form of a software functional module and sold or used as an independent product, it may be stored on a single computer readable storage medium.

  The storage medium may be a read only memory (ROM), a magnetic disk, an optical disk, or the like.

  In the description of the present invention, the description referring to terms such as “one embodiment”, “some embodiments”, “examples”, “specific examples”, or “some examples” Specific features, configurations, materials, or characteristics described in connection with the embodiments or examples are included in at least one embodiment or example of the present invention. In this specification, exemplary depictions of the above terms are not necessarily indicative of the same embodiments or examples. In addition, the specific features, configurations, materials, or characteristics described can be combined appropriately in any one or more embodiments or examples.

  As mentioned above, although the Example of this invention was shown and demonstrated, said Example is only an illustrative description and does not limit this invention. Those skilled in the art can make various changes, modifications, changes and modifications to these embodiments within the scope of the present invention without departing from the principle and spirit of the present invention. The scope of the invention is limited by the claims and their equivalents.

Claims (42)

Determining a time parameter for transmitting current data;
Acquiring 2 ^N different numerical values included in the N-bit data and time intervals based on the time parameter, the time intervals corresponding to the different numerical values are different, and N ≧ 1;
Obtaining a current data bit string to be transmitted;
Grouping the data bit string so that each group of data has N bits;
Transmitting the data of the group based on the acquired correspondence relationship so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group,
A data transmission method characterized by the above. For each group of data, the step of transmitting the group data is:
M signals are generated and transmitted, and the time interval between the start time of each signal and the start time of one adjacent previous signal is a time interval corresponding to the data value of the group, M ≧ 1, and M is a natural number,
The data transmission method according to claim 1. The step of generating the M signals includes:
Generating M low level pulses according to the time interval;
The data transmission method according to claim 2. Before sending the first group of data,
Generating and transmitting K handshake signals, further comprising K ≧ 2 and K is an integer;
The data transmission method according to any one of claims 1 to 3. Satisfying a preset relationship between the K handshake signals;
The data transmission method according to claim 4, wherein: The K handshake signals include a time parameter;
The data transmission method according to claim 5, wherein: Satisfying a preset relationship between the K handshake signals,
The first time interval includes satisfying a preset relationship between the first time interval and the second time interval, and the first time interval corresponds to the start time of the i-th handshake signal and the (i−1) -th time. The second time interval is a time interval between the start time of the i-th handshake signal and the start time of the (i + 1) th handshake signal. I = 2, 4,..., 2j, j = (K-1) / 2, K ≧ 3, and K is an odd number.
The data transmission method according to claim 5 or 6, characterized in that A first time interval group and / or a second time interval group is determined based on the time parameter, the first time interval group including at least one first time interval, and the second time interval. An interval group includes at least one second time interval;
The data transmission method according to claim 7. The step of generating the K handshake signals includes:
Generating K low-level pulses according to the first time interval and the second time interval;
The data transmission method according to claim 7 or 8, characterized in that Switching a currently used time parameter to a new time parameter according to a preset rule, and determining the new time parameter as a time parameter for transmitting current data;
Updating the correspondence based on a time parameter for transmitting current data;
Further comprising the step of transmitting data according to the updated correspondence.
The data transmission method according to claim 1, wherein the data transmission method is a data transmission method. Determining a time parameter for transmitting current data;
Receive X signals, determine the time interval between each start time of two adjacent signals in the X signals, and obtain X-1 time intervals, where X is a positive integer And a step where X>1;
Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in the X-1 time intervals is obtained and transmitted in the S time intervals. The numerical value transmitted in the S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data. Yes, when S> 1, the time intervals in the S time intervals are the same, X and S are both positive integers, and S ≦ X−1, N ≧ 1, Including,
A data receiving method. Before obtaining the numerical value transmitted in the first consecutive S time intervals in the X-1 time intervals,
Obtaining a correspondence relationship between 2 ^N different numerical values included in the N-bit data and the time interval based on the time parameter, and further including different time intervals corresponding to the different numerical values;
The data receiving method according to claim 11. X-1 = n * S, n ≧ 1, and n is an integer.
The data receiving method according to claim 11 or 12, characterized in that: Receiving the X signals comprises:
Including the step of detecting X low level pulses,
The data receiving method according to claim 11, wherein the data receiving method is a data receiving method. Before receiving the X signals,
Receiving K signals, detecting whether or not a predetermined relationship is satisfied between the K signals, and further comprising the steps of K ≧ 2 and K is an integer,
The data receiving method according to claim 11, wherein the data receiving method is a data receiving method. Determining a time parameter for transmitting the current data;
Determining a time parameter based on the K signals;
The data receiving method according to claim 15, wherein: Detecting whether or not the K signals satisfy a preset relationship;
A time interval between the K signals is detected, and it is determined whether or not a predetermined relationship is satisfied between the first time interval and the second time interval, and the first time interval is determined. The interval is a time interval between the start time of the i-th signal and the start time of the (i-1) -th signal, and the second time interval is the start time of the i-th signal and the (i + 1) -th signal. Is the time interval from the start time of the signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number,
Performing the step of receiving the X signals if the first time interval and the second time interval satisfy a preset relationship;
The data receiving method according to claim 15 or 16, characterized in that: Determining a time parameter based on the K signals comprises:
Determining a first time interval group and / or a second time interval group, wherein the first time interval group includes at least one of the first time intervals, and wherein the second time interval group is at least one; Including the second time interval;
Determining the time parameter based on the first time interval group and / or the second time interval group;
The data receiving method according to claim 17. Receiving the K signals comprises:
Including the step of detecting K low level pulses,
The data receiving method according to claim 15, wherein the data receiving method is a data receiving method. According to a preset rule, the currently used time parameter is switched to the new time parameter, the new time parameter is determined as the time parameter for transmitting the current data,
Receiving the X signals, determining a time interval between the start times of two adjacent signals in the X signals, obtaining X-1 time intervals, wherein X is a positive integer; Yes, and X> 1
Based on the time parameter for transmitting the current data, obtain a numerical value corresponding to the individual time interval for each successive S time intervals in X-1 time intervals, and transmit in S time intervals The numerical value transmitted in S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is one of 2 ^N different numerical values included in the N-bit data, and S If> 1, each time interval in the S time intervals is the same;
The data receiving method according to any one of claims 11 to 18. Receiving the X signals comprises:
Receiving Y + 1 signals, removing noise in Y + 1 signals to obtain X signals, including Y + 1 ≧ X,
The data receiving method according to claim 11, wherein: A time parameter determination unit for determining a time parameter for transmitting current data;
Based on the time parameter, it is for obtaining the correspondence between 2 ^N different numerical values included in the N-bit data and the time interval, and the time intervals corresponding to the different numerical values are different, and N ≧ 1 A time interval acquisition unit;
A data bit string acquisition unit for acquiring a current data bit string to be transmitted and performing grouping on the data bit string so that each group of data has N bits;
A transmission unit for transmitting the data of the group so as to indicate the data of the group at a time interval corresponding to the numerical value of the data of each group based on the acquired correspondence.
A data transmitting apparatus characterized by that. For each group of data, the transmission unit transmits the group data,
The transmission unit generates and transmits M signals, and the time interval between the start time of each of the signals and the start time of one adjacent previous signal corresponds to the value of the data of the group An interval, including M ≧ 1, and M is a natural number,
The data transmission apparatus according to claim 22. The transmitting unit generating M signals comprises:
The transmitting unit generates M low level pulses based on the time interval;
24. The data transmission apparatus according to claim 23. A handshake signal transmission unit for generating and transmitting K handshake signals, where K ≧ 2 and K is an integer;
25. The data transmission device according to claim 22, wherein the data transmission device is a data transmission device. Satisfying a preset relationship between the K handshake signals;
26. The data transmission apparatus according to claim 25. The K handshake signals include a time parameter;
26. The data transmission apparatus according to claim 25. Satisfying a preset relationship between the K handshake signals includes satisfying a preset relationship between a first time interval and a second time interval, 1 time interval is a time interval between the start time of the i-th handshake signal and the start time of the i-1th handshake signal, and the second time interval is the i-th handshake. A time interval between the start time of the signal and the start time of the (i + 1) th handshake signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number,
28. The data transmitting apparatus according to claim 26 or 27. Determining a first time interval group and / or a second time interval group based on a time parameter, wherein the first time interval group includes at least one of the first time intervals; A handshake signal time interval determination unit, wherein the second time interval group includes at least one second time interval;
29. The data transmission device according to claim 28. The handshake signal transmitting unit generates K handshake signals.
The handshake signal transmitting unit generates K low-level pulses according to the first time interval and the second time interval;
30. The data transmission device according to claim 27, wherein the data transmission device is a data transmission device. Pre-set rules switch the currently used time parameter to the new time parameter, determine the new time parameter as the time parameter carrying the current data, and trigger the time interval acquisition unit based on the new time parameter A time parameter update unit for updating the correspondence relationship,
A time interval acquisition unit for updating the correspondence based on a time parameter for transmitting current data;
A transmission unit for transmitting data according to the updated correspondence relationship,
The data transmission device according to any one of claims 22 to 30, wherein the data transmission device is a data transmission device. A time parameter determination unit for determining a time parameter for transmitting current data;
Receiving X signals, determining a time interval between the start times of two adjacent signals in the X signals, and obtaining X-1 time intervals; X A receiving unit in which is a positive integer and X>1;
Based on the determined time parameter, a numerical value corresponding to an individual time interval for each successive S time intervals in the X-1 time intervals is obtained and transmitted in the S time intervals. A numerical value transmitted in the S time intervals is a numerical value corresponding to the individual time interval, and the numerical value is included in 2 ^N different values included in the N-bit data. A data acquisition unit that is one of the numerical values, and in the case of S> 1, each time interval in the S time intervals is the same.
A data receiving apparatus. Before the data acquisition unit acquires the numerical value transmitted in the first consecutive S time intervals in the X-1 time intervals, it is included in the N-bit data based on the time parameter. A time interval acquisition unit for acquiring a correspondence relationship between ^N different numerical values and time intervals;
Different time intervals corresponding to different numbers,
33. The data receiving device according to claim 32. X-1 = n * S, n ≧ 1, and n is an integer.
34. The data receiving apparatus according to claim 32 or 33. The receiving unit receives X signals,
The receiving unit has detected X low level pulses;
35. The data receiving device according to claim 32, wherein the data receiving device is a data receiving device. A handshake signal receiving unit for receiving K signals and detecting whether or not a predetermined relationship is satisfied between the K signals;
36. A data receiving apparatus according to any one of claims 32 to 35, wherein: Determining a time parameter for transmitting the current data by the time parameter determining unit;
A time parameter determining unit includes determining a time parameter based on the K signals;
37. A data receiving apparatus according to claim 36. The handshake signal receiving unit receives K signals.
The handshake signal receiving unit detects a time interval between the K signals and determines whether or not the first time interval and the second time interval satisfy a preset relationship; The first time interval is a time interval between the start time of the i-th signal and the start time of the (i-1) th signal, and the second time interval is the start time of the i-th signal. And the start time of the (i + 1) th signal, i = 2, 4,..., 2j, j = (K−1) / 2, K ≧ 3, and K is an odd number,
Notifying the receiving unit to perform the step of receiving X signals if the predetermined relationship between the first time interval and the second time interval satisfies a preset relationship;
38. A data receiving apparatus according to claim 36 or 37. Determining a time parameter for transmitting the current data by the time parameter determining unit;
The time parameter determining unit determines a first time interval group and / or a second time interval group, the first time interval group including at least one of the first time intervals, and the second time interval; An interval group includes at least one second time interval, and determining a time parameter based on the first time interval group and / or the second time interval group;
40. A data receiving apparatus according to claim 38. The handshake signal receiving unit receives K signals.
The handshake signal receiving unit detects K low level pulses;
40. The data receiving device according to claim 36, wherein the data receiving device is a data receiving device. A time parameter update unit for switching a currently used time parameter to a new time parameter according to a preset rule and determining the new time parameter as a time parameter for transmitting current data;
Receiving X signals, determining a time interval between the start times of two adjacent signals in the X signals, and obtaining X-1 time intervals, wherein The receiving unit wherein X is a positive integer and X>1;
Based on the time parameter for transmitting the current data acquired by the time parameter update unit, obtain a numerical value corresponding to an individual time interval for each successive S time intervals in X-1 time intervals; It is one that obtains a numerical value that is transmitted in the S time interval is a numerical value numerical value transmitted in the S time intervals corresponding to each time interval, 2 ^N pieces of numerical values is included in the N-bit data A data acquisition unit in which each time interval in the S time intervals is the same.
41. A data receiving apparatus according to claim 39 or 40, wherein: Further comprising a filtering unit for receiving Y + 1 signals, removing noise in the Y + 1 signals, obtaining X signals and transmitting them to the receiving unit, wherein Y + 1 ≧ X;
42. The data receiving device according to claim 32, wherein the data receiving device is a data receiving device.

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