CN111950941A - Industrial design system for improving interaction experience and interaction method thereof - Google Patents

Abstract

An industrial design system for improving interaction experience and an interaction method thereof, wherein a module running on a receiver of a control signal comprises: a treatment module and a delivery module, where: a processing module for identifying a response time point, wherein the response time point is used for instructing a transmitter of a control signal to transmit the control signal to a receiver of the control signal by virtue of the response time point; and the transmission module is used for transmitting the time point of the response to the transmission party of the control signal. The method effectively avoids the defect that the control signal receiving party in the intelligent experience tester for achieving the product industrial design expression user experience test method in the prior art can not determine whether the control signal transmitting party receives the command requiring to transmit the control signal or not, so that the command requiring to transmit the control signal is transmitted to the control signal transmitting party again, and the software and hardware resources of the link are formed.

Description

Industrial design system for improving interaction experience and interaction method thereof

Technical Field

The invention relates to the technical field of industrial design, in particular to an industrial design system for improving interaction experience and an interaction method thereof.

Background

Industrial design is a creative activity whose purpose is to create versatile qualities for goods, processes, services and the systems they constitute throughout their life cycle. Industrial design is also a specialized service task that favors the appearance, functionality, and use value of products and product lines for the benefit of both the user and the manufacturer.

And the three-dimensional design in the industrial design is the basis of a new generation of digital, virtual and intelligent design platform. The method is a new design method which is established on the basis of plane and two-dimensional design and enables the design target to be more three-dimensional and more visualized.

Therefore, in the industrial design stage of product development, especially in the industrial design of instruments such as self-closing instruments or art products, the user experience evaluation is often required to be carried out on the design scheme to help the user obtain psychological comfort and emotion coincidence in the whole consumption process, so that the intelligent experience tester for achieving the test method for expressing the user experience of the product industrial design is achieved, which comprises a test terminal and a test material library, wherein the test terminal is wirelessly connected with the test material library in a GPRS mode, the intelligent experience tester also comprises a control signal bidirectional transmission module I arranged on the test terminal and a control signal bidirectional transmission module II arranged on the test material library, control signals can be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II, and at present, when the control signal transmission is carried out between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II, the control signal transmitter can only execute the control signal transmission when the current link is not crowded.

In the standard specification of GPRS, a transmitter of a control signal transmits the control signal by inquiring and then transmitting the control signal, that is, when a receiver of the control signal instructs the transmitter of the control signal to transmit the control signal at a set time, the transmitter of the control signal cannot respond to the receiver of the control signal at the set time because a link is crowded by other GPRS devices, and the receiver of the control signal cannot receive the control signal responded to by the transmitter of the control signal at the set time; therefore, the receiver of the control signal cannot determine whether the transmitter of the control signal receives the command requesting to transmit the control signal without error, and then transmits the command requesting to transmit the control signal to the transmitter of the control signal again, thereby forming the loss of the software and hardware resources of the link.

Disclosure of Invention

In order to solve the above problems, the present invention provides an industrial design system for improving interactive experience and an interactive method thereof, which effectively avoid the defect that in the prior art, a receiver of a control signal in an intelligent experience tester for achieving a product industrial design expression user experience test method cannot determine whether a transmitter of the control signal receives a command requiring transmission of the control signal without error, and thus, the receiver needs to transmit the command requiring transmission of the control signal to the transmitter of the control signal again, so as to form software and hardware resources of a link.

In order to overcome the defects in the prior art, the invention provides a solution for an industrial design system and an interaction method thereof for improving interaction experience, which comprises the following specific steps:

an industrial design system for enhancing an interaction experience, comprising:

the test terminal and the test material library are used for achieving an intelligent experience tester for expressing a user experience test method in product industrial design, and the test terminal and the test material library are in wireless connection in a GPRS mode;

the device also comprises a control signal bidirectional transmission module I arranged on the test terminal and a control signal bidirectional transmission module II arranged on the test material library, wherein control signals can be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II;

the control signal bidirectional transmission module I transmits a control signal to the control signal bidirectional transmission module II, the control signal bidirectional transmission module I is a transmission party of the control signal, and the control signal bidirectional transmission module II is a receiving party of the control signal; the control signal bidirectional transmission module II transmits a control signal to the control signal bidirectional transmission module I, the control signal bidirectional transmission module II is a transmission party of the control signal, and the control signal bidirectional transmission module I is a receiving party of the control signal;

the module operating on the receiver of the control signal comprises: a treatment module and a delivery module, where:

a processing module for identifying a response time point, wherein the response time point is used for instructing a transmitter of a control signal to transmit the control signal to a receiver of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the time point of the response to the transmission party of the control signal.

The processing module's affirming response time point includes:

determining the use degree of the current carrier frequency;

and acquiring the response time point corresponding to the determined utilization degree of the current carrier frequency by means of the preset association degree between the utilization degree and the response time point.

The handling module determines the association degree between the usage degree and the response time point, and comprises:

cutting a time interval corresponding to a carrier frequency for transmitting a control signal into different time periods, wherein the time periods comprise more than one time point;

identifying the correlation degree between the different time periods and the use degree;

here, the larger the size of the degree of use, the larger the amount of time points that are present in the corresponding period and are not the same, and the intervals between the time points are intermittent; the smaller the usage degree, the smaller the amount of time points in the corresponding time period.

The handling module determines the utilization degree of the current carrier frequency, and comprises the following steps:

and (2) determining the use degree of the carrier frequency by using the formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jThe using degree of the corresponding carrier frequency transmitted by the j secondary command for transmitting the control signal is explained; z₀Is 1; y is NULL or 1.

The response time point includes more than one time point.

If the response time point comprises a plurality of time points, the plurality of time points are consistent with the time point continuously, or the plurality of time points are consistent with the time point discontinuously.

If the plurality of time points are consistent with the time points and are discontinuous, the time distances between the adjacent time points in the plurality of time points are the same, or the time distances between the adjacent time points in the plurality of time points are different.

The transmitting module transmits the response time point to a transmitting party of the control signal, and comprises:

packaging the response time point in a command requiring to transmit a control signal and transmitting the command to a transmitter of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

The module operating on the transmission side of the control signal comprises: a receive module and a pass-through module, where:

the receiving module is used for receiving a response time point transmitted by a receiving party of the control signal, and the response time point is used for commanding the transmitting party of the control signal to transmit the control signal to the receiving party of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the control signal to the receiver of the control signal by means of the response time point.

The method for controlling signals to interact between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II operates on a receiving side of the control signals and comprises the following steps:

SA-1, affirming a response time point, wherein the response time point is used for commanding a transmitter of the control signal to transmit the control signal to a receiver of the control signal by the response time point;

the following describes in detail how the receiver of the control signal recognizes the response timing.

Specifically, the receiver of the control signal identifies the usage of the current carrier frequency, and further obtains the response time corresponding to the identified usage of the current carrier frequency by the association between the usage and the response time set in advance.

Furthermore, the responding time point in the invention can be a time point, a time period or a plurality of time points;

the response time point has more than one time point;

if the response time point has a plurality of time points, the plurality of time points are consistent with the time point and are not continuous, or the plurality of time points are consistent with the time point and are not continuous;

if the time points are consistent with the time points and are discontinuous, the time intervals of the adjacent time points in the time points are the same, or the time intervals of the adjacent time points in the time points are different.

In the invention, the receiver of the control signal can be the affirmed responding time before transmitting the command of requesting to transmit the control signal to the transmitter of the control signal; the secondary signal link can be constructed at the transmitting side of the control signal, and the secondary signal link can be a period from the transmitting side of the control signal linking into the receiving side of the control signal to the transmitting side of the control signal disconnecting from the receiving side of the control signal.

The method for determining the use degree of the carrier frequency comprises the following steps of determining the use degree of the carrier frequency by using a formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jExplain the j th timeThe command for transmitting the control signal is required to transmit the utilization degree of the corresponding carrier frequency; z₀Is 1; y is NULL or 1.

Further, in the present invention, in the case of a command requiring the transmission of a control signal for the j-1 th transmission, if the transmission side of the control signal transmits the control signal at the first available response time point, Y is 1, otherwise, Y is NULL.

The method for determining the correlation between the usage degree and the response time by the receiver of the control signal comprises the following steps.

SB-1, cutting the time interval corresponding to the carrier frequency used for transmitting the control signal into different time intervals, wherein the time intervals have more than one time point.

SB-2, the degree of association between the period and the degree of usage is not identified as such.

Here, the larger the size of the degree of use, the larger the amount of time points that are present in the corresponding period and are not the same, and the intervals between the time points are intermittent; the smaller the usage degree, the smaller the amount of time points in the corresponding time period.

Where S is a natural number greater than zero.

In addition, the acquired subintervals are serialized; here, the smaller the amount of the time point of response, the earlier the sequence thereof; for the consistent number of the response time points, the smaller the time interval between the response time points, the earlier the sequence.

SB-3, serializing the utilization by virtue of its size going from low to high, i.e. the smaller the value of the utilization, the earlier its sequence;

SB-4, by virtue of the sequence, the degree of association between the different subranges and the degree of use is identified.

And SA-2, transmitting the time point of the response to the transmitting party of the control signal.

In the invention, the response time point is packaged in a command requiring to transmit a control signal and transmitted to a transmitting party of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

Further, it is ensured that the recipient of the control signal can return an assertionIn the present invention, the transmission side of control signal should transmit at a certain time, and the capacity added in the command is ⌈ log₂Command at bit S ⌉.

The method for controlling signals to be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II operates on the transmission side of the control signals and comprises the following steps:

SC-1, a response time point transmitted by the receiver of the received control signal, wherein the response time point is used for commanding the transmitter of the control signal to transmit the control signal to the receiver of the control signal by the response time point;

SC-2, by means of the response timing, transmits a control signal to a recipient of the control signal.

The correlation degree between the use degree and the response time point can be determined by a preset rule between the receiving party of the control signal and the transmitting party of the control signal, and the transmitting party of the control signal can also store the correlation degree; under the condition that the transmitter of the control signal receives the response time transmitted by the receiver of the control signal, if the response time is determined to be not matched with the current usage degree of the carrier frequency, a new response time can be determined by the relevance degree, and the determined new response time is notified to the receiver of the control signal through a second command.

The invention has the beneficial effects that:

the invention identifies a response time point, wherein the response time point is used for transmitting a control signal to a receiver of the control signal by a transmitter of a command control signal through the response time point; and transmitting the response time point to a transmitting side of the control signal; by constructing a response mode between the receiver of the control signal and the transmitter of the control signal, i.e. the receiver of the control signal recognizes the response time and transmits the recognized response time to the transmitter of the control signal, the transmitter of the control signal transmits the control signal to the receiver of the control signal by the response time, so as to indicate whether the receiver of the control signal receives the command requesting to transmit the control signal without error, the defect of link hardware loss caused by the fact that the receiver of the control signal has to transmit the command requesting to transmit the control signal again because the transmitter of the control signal cannot be recognized as the command requesting to transmit the control signal is not received without error is overcome, and in addition, the transmitter of the control signal can flexibly achieve the response of the control signal by the response time transmitted by the receiver of the control signal, the system error correction capability during control signal transmission is enhanced. The method effectively avoids the defect that the control signal receiving party in the intelligent experience tester for achieving the product industrial design expression user experience test method in the prior art can not determine whether the control signal transmitting party receives the command requiring to transmit the control signal or not, so that the command requiring to transmit the control signal is transmitted to the control signal transmitting party again, and the software and hardware resources of the link are formed.

Drawings

Fig. 1 is a flow chart of a method for enabling control signals to be exchanged between the control signal bidirectional transfer module i and the control signal bidirectional transfer module ii, which is operated on a receiving side of the control signals.

Fig. 2 is a flowchart of a method of how the receiver of the control signal recognizes the correlation between the usage degree and the response time point according to the present invention.

Fig. 3 is a flow chart of a method for enabling control signals to be exchanged between the control signal bidirectional transfer module i and the control signal bidirectional transfer module ii, which is executed on a control signal receiver, according to the present invention.

Detailed Description

The invention will be further described with reference to the following figures and examples.

As shown in fig. 1 and 3, an industrial design system for improving an interaction experience includes:

the test terminal and the test material library of the intelligent experience tester are used for achieving the product industrial design expression user experience test method, and the test terminal can be a computer; the test terminal and the test material library execute wireless connection in a GPRS mode;

the system comprises a testing terminal, a control signal bidirectional transmission module I and a control signal bidirectional transmission module II, wherein the testing terminal is used for receiving a control signal transmitted by a user experience system; the control signal bidirectional transmission module II is arranged on the test material library and is used for receiving a control signal transmitted from the interior of the self-test terminal and enabling the control signal generated in the interior of the material library to flow to the test terminal, namely the control signal bidirectional transmission module I and the control signal bidirectional transmission module II can exchange control signals;

the control signal bidirectional transmission module I transmits a control signal to the control signal bidirectional transmission module II, the control signal bidirectional transmission module I is a transmission party of the control signal, and the control signal bidirectional transmission module II is a receiving party of the control signal; the control signal bidirectional transmission module II transmits a control signal to the control signal bidirectional transmission module I, the control signal bidirectional transmission module II is a transmission party of the control signal, and the control signal bidirectional transmission module I is a receiving party of the control signal;

the test terminal and the test material library are used for achieving an intelligent experience tester for expressing a user experience test method in product industrial design, and the test terminal and the test material library are in wireless connection in a GPRS mode;

the device also comprises a control signal bidirectional transmission module I arranged on the test terminal and a control signal bidirectional transmission module II arranged on the test material library, wherein control signals can be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II;

the control signal bidirectional transmission module I transmits a control signal to the control signal bidirectional transmission module II, the control signal bidirectional transmission module I is a transmission party of the control signal, and the control signal bidirectional transmission module II is a receiving party of the control signal; the control signal bidirectional transmission module II transmits a control signal to the control signal bidirectional transmission module I, the control signal bidirectional transmission module II is a transmission party of the control signal, and the control signal bidirectional transmission module I is a receiving party of the control signal;

the module operating on the receiver of the control signal comprises: a treatment module and a delivery module, where:

a processing module for identifying a response time point, wherein the response time point is used for instructing a transmitter of a control signal to transmit the control signal to a receiver of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the time point of the response to the transmission party of the control signal.

The processing module's affirming response time point includes:

determining the use degree of the current carrier frequency;

and acquiring the response time point corresponding to the determined utilization degree of the current carrier frequency by means of the preset association degree between the utilization degree and the response time point.

The handling module determines the association degree between the usage degree and the response time point, and comprises:

cutting a time interval corresponding to a carrier frequency for transmitting a control signal into different time periods, wherein the time periods comprise more than one time point;

identifying the correlation degree between the different time periods and the use degree;

here, the larger the size of the degree of use, the larger the amount of time points that are present in the corresponding period and are not the same, and the intervals between the time points are intermittent; the smaller the usage degree, the smaller the amount of time points in the corresponding time period.

The handling module determines the utilization degree of the current carrier frequency, and comprises the following steps:

and (2) determining the use degree of the carrier frequency by using the formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jThe using degree of the corresponding carrier frequency transmitted by the j secondary command for transmitting the control signal is explained; z₀Is 1; y is NULL or 1.

The response time point includes more than one time point.

If the response time point comprises a plurality of time points, the plurality of time points are consistent with the time point continuously, or the plurality of time points are consistent with the time point discontinuously.

If the plurality of time points are consistent with the time points and are discontinuous, the time distances between the adjacent time points in the plurality of time points are the same, or the time distances between the adjacent time points in the plurality of time points are different.

The transmitting module transmits the response time point to a transmitting party of the control signal, and comprises:

packaging the response time point in a command requiring to transmit a control signal and transmitting the command to a transmitter of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

Further, a response time point is determined, wherein the response time point is used for instructing the transmitting party of the control signal to transmit the control signal to the receiving party of the control signal by virtue of the response time point; and transmitting the response time point to a transmitting side of the control signal; by establishing a response mechanism between the receiver of the control signal and the transmitter of the control signal, i.e. the receiver of the control signal recognizes the response time point and transmits the recognized response time point to the transmitter of the control signal, the transmitter of the control signal transmits the control signal to the receiver of the control signal by the response time point, so as to indicate whether the receiver of the control signal receives the command requesting to transmit the control signal without error, the defect of link hardware loss caused by the fact that the receiver of the control signal needs to transmit the command requesting to transmit the control signal again to the transmitter of the control signal because the transmitter of the control signal cannot be recognized as the command requesting to transmit the control signal without error is overcome, in addition, the transmitter of the control signal can flexibly achieve the response of the control signal by the time point transmitted by the receiver of the control signal, the system error correction capability during control signal transmission is enhanced.

The module operating on the transmission side of the control signal comprises: a receive module and a pass-through module, where:

the receiving module is used for receiving a response time point transmitted by a receiving party of the control signal, and the response time point is used for commanding the transmitting party of the control signal to transmit the control signal to the receiving party of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the control signal to the receiver of the control signal by means of the response time point.

According to the mode of inquiring before transmitting in the current GPRS standard specification, under the specific application, the mode also has the defect that certain signals cannot be transmitted at the determined position, and the defect can not ensure the effect of the current GPRS mode; since the response information cannot guarantee real-time transmission at a constant time, the ability to transmit signals via GPRS standard specifications is reduced when the link is congested.

To overcome the above-mentioned drawbacks, the present invention provides a method and system for transmitting a control signal, wherein a response time point is determined, and the response time point is used for instructing a transmitter of the control signal to transmit the control signal to a receiver of the control signal by the response time point; and transmitting the response time point to a transmitting side of the control signal; by establishing a response mechanism between the receiver of the control signal and the transmitter of the control signal, i.e. the receiver of the control signal recognizes the response time point and transmits the recognized response time point to the transmitter of the control signal, the transmitter of the control signal transmits the control signal to the receiver of the control signal by the response time point, so as to indicate whether the receiver of the control signal receives the command requesting to transmit the control signal without error, the defect of link hardware loss caused by the fact that the receiver of the control signal needs to transmit the command requesting to transmit the control signal again to the transmitter of the control signal because the transmitter of the control signal cannot be recognized as the command requesting to transmit the control signal without error is overcome, in addition, the transmitter of the control signal can flexibly achieve the response of the control signal by the time point transmitted by the receiver of the control signal, the system error correction capability during control signal transmission is enhanced.

The method for controlling signals to interact between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II operates on a receiving side of the control signals and comprises the following steps:

SA-1, affirming a response time point, wherein the response time point is used for commanding a transmitter of the control signal to transmit the control signal to a receiver of the control signal by the response time point;

in the invention, before transmitting the command of requesting to transmit the control signal to the transmitting party of the control signal, the receiving party of the control signal identifies the response time point, and the response time point can instruct the transmitting party of the control signal to transmit the timing of transmitting the control signal to the receiving party of the control signal, thus effectively avoiding the problem of link hardware and software loss caused by the fact that the receiving party of the control signal has to transmit the command of requesting to transmit the control signal again to the transmitting party of the control signal because the transmitting party of the control signal can not be identified as the command of requesting to transmit the control signal without error; especially, the control signal is transmitted in the GPRS network, so that the control signal transmitting party can be ensured to transmit the control signal to the control signal receiving party at the authorized place, and the probability of selecting a plurality of types in the transmission mode after the inquiry is carried out can be ensured, thereby overcoming the phenomenon that the control signal cannot be responded to the control signal receiving party in real time after other systems of the link are crowded.

The following describes in detail how the receiver of the control signal recognizes the response timing.

Specifically, the receiver of the control signal identifies the usage of the current carrier frequency, and further obtains the response time corresponding to the identified usage of the current carrier frequency by the association between the usage and the response time set in advance.

Furthermore, the responding time point in the invention can be a time point, a time period or a plurality of time points;

the response time point has more than one time point;

if the response time point has a plurality of time points, the plurality of time points are consistent with the time point and are not continuous, or the plurality of time points are consistent with the time point and are not continuous;

if the time points are consistent with the time points and are discontinuous, the time intervals of the adjacent time points in the time points are the same, or the time intervals of the adjacent time points in the time points are different.

In the invention, the receiver of the control signal can be the affirmed responding time before transmitting the command of requesting to transmit the control signal to the transmitter of the control signal; the secondary signal link can be constructed at the transmitting side of the control signal, and the secondary signal link can be a period from the transmitting side of the control signal linking into the receiving side of the control signal to the transmitting side of the control signal disconnecting from the receiving side of the control signal.

The method for determining the use degree of the carrier frequency comprises the following steps of determining the use degree of the carrier frequency by using a formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jThe using degree of the corresponding carrier frequency transmitted by the j secondary command for transmitting the control signal is explained; z₀Is 1; y is NULL or 1.

Further, in the present invention, in the case of a command requiring the transmission of a control signal for the j-1 th transmission, if the transmission side of the control signal transmits the control signal at the first available response time point, Y is 1, otherwise, Y is NULL.

The method for determining the correlation between the usage degree and the response time by the receiver of the control signal comprises the following steps.

SB-1, cutting the time interval corresponding to the carrier frequency used for transmitting the control signal into different time intervals, wherein the time intervals have more than one time point.

SB-2, the degree of association between the period and the degree of usage is not identified as such.

Here, the larger the size of the degree of use, the larger the amount of time points that are present in the corresponding period and are not the same, and the intervals between the time points are intermittent; the smaller the usage degree, the smaller the amount of time points in the corresponding time period.

As follows: initially, the range of {0, 1} is divided into SUninterrupted and non-intersecting subranges: { {0, T₁}，{T₁,T₂},..,{T_S-11} }, here 0< T₁< T₂…< T_S-1<1, the individual subranges can be the same or different in size.

Where S is a natural number greater than zero.

In addition, the acquired subintervals are serialized; here, the smaller the amount of the time point of response, the earlier the sequence thereof; for the consistent number of the response time points, the smaller the time interval between the response time points, the earlier the sequence.

SB-3, serializing the utilization by virtue of its size going from low to high, i.e. the smaller the value of the utilization, the earlier its sequence;

SB-4, by virtue of the sequence, the degree of association between the different subranges and the degree of use is identified.

And SA-2, transmitting the time point of the response to the transmitting party of the control signal.

In the invention, the response time point is packaged in a command requiring to transmit a control signal and transmitted to a transmitting party of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

Further, in order to ensure that the receiver of the control signal can transmit the identified response time to the transmitter of the control signal, the present invention must add ⌈ log as capacity to the command₂Command at bit S ⌉.

According to the invention, a response time point is determined, and the response time point is used for transmitting the control signal to a receiver of the control signal by a transmitter of the command control signal through the response time point; and transmitting the response time point to a transmitting side of the control signal; by constructing a response mode between the receiver of the control signal and the transmitter of the control signal, i.e. the receiver of the control signal recognizes the response time and transmits the recognized response time to the transmitter of the control signal, the transmitter of the control signal transmits the control signal to the receiver of the control signal by the response time, so as to indicate whether the receiver of the control signal receives the command requesting to transmit the control signal without error, the defect of link hardware loss caused by the fact that the receiver of the control signal has to transmit the command requesting to transmit the control signal again because the transmitter of the control signal cannot be recognized as the command requesting to transmit the control signal is not received without error is overcome, and in addition, the transmitter of the control signal can flexibly achieve the response of the control signal by the response time transmitted by the receiver of the control signal, the system error correction capability during control signal transmission is enhanced.

The method for controlling signals to be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II operates on the transmission side of the control signals and comprises the following steps:

SC-1, a response time point transmitted by the receiver of the received control signal, wherein the response time point is used for commanding the transmitter of the control signal to transmit the control signal to the receiver of the control signal by the response time point;

SC-2, by means of the response timing, transmits a control signal to a recipient of the control signal.

In the invention, the relevance between the usage degree and the response time point can be identified by a preset rule between the receiving party of the control signal and the transmitting party of the control signal, and the transmitting party of the control signal can also store the relevance; under the condition that the transmitter of the control signal receives the response time transmitted by the receiver of the control signal, if the response time is determined to be not matched with the current usage degree of the carrier frequency, a new response time can be determined by the relevance degree, and the determined new response time is notified to the receiver of the control signal through a second command.

The present invention has been described in an illustrative manner by the embodiments, and it should be understood by those skilled in the art that the present disclosure is not limited to the embodiments described above, but is capable of various changes, modifications and substitutions without departing from the scope of the present invention.

Claims (10)

1. An industrial design system for enhancing interactive experience, comprising:

the test terminal and the test material library are used for achieving an intelligent experience tester for expressing a user experience test method in product industrial design, and the test terminal and the test material library are in wireless connection in a GPRS mode;

the device also comprises a control signal bidirectional transmission module I arranged on the test terminal and a control signal bidirectional transmission module II arranged on the test material library, wherein control signals can be interacted between the control signal bidirectional transmission module I and the control signal bidirectional transmission module II;

the control signal bidirectional transmission module I transmits a control signal to the control signal bidirectional transmission module II, the control signal bidirectional transmission module I is a transmission party of the control signal, and the control signal bidirectional transmission module II is a receiving party of the control signal; the control signal bidirectional transmission module II transmits a control signal to the control signal bidirectional transmission module I, the control signal bidirectional transmission module II is a transmission party of the control signal, and the control signal bidirectional transmission module I is a receiving party of the control signal;

the module operating on the receiver of the control signal comprises: a treatment module and a delivery module, where:

a processing module for identifying a response time point, wherein the response time point is used for instructing a transmitter of a control signal to transmit the control signal to a receiver of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the time point of the response to the transmission party of the control signal.

2. The system of claim 1, wherein the processing module recognizes a response time point, comprising:

determining the use degree of the current carrier frequency;

acquiring a response time point corresponding to the determined utilization degree of the current carrier frequency by means of a preset association degree between the utilization degree and the response time point;

the handling module determines the association degree between the usage degree and the response time point, and comprises:

cutting a time interval corresponding to a carrier frequency for transmitting a control signal into different time periods, wherein the time periods comprise more than one time point;

and identifying a degree of correlation between the time period and the degree of use.

3. The system of claim 1, wherein the handling module recognizes a degree of use of a current carrier frequency, comprising:

and (2) determining the use degree of the carrier frequency by using the formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jThe using degree of the corresponding carrier frequency transmitted by the j secondary command for transmitting the control signal is explained; z₀Is 1; y is NULL or 1.

4. The system of claim 1, wherein the response time points include one or more time points;

if the response time point comprises a plurality of time points, the plurality of time points are consistent with the time point and are not continuous, or the plurality of time points are consistent with the time point and are discontinuous;

if the plurality of time points are consistent with the time points and are discontinuous, the time distances between adjacent time points in the plurality of time points are the same, or the time distances between adjacent time points in the plurality of time points are different;

the transmitting module transmits the response time point to a transmitting party of the control signal, and comprises:

packaging the response time point in a command requiring to transmit a control signal and transmitting the command to a transmitter of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

5. The system of claim 1, wherein the module running on the transfer side of the control signal comprises: a receive module and a pass-through module, where:

the receiving module is used for receiving a response time point transmitted by a receiving party of the control signal, and the response time point is used for commanding the transmitting party of the control signal to transmit the control signal to the receiving party of the control signal by virtue of the response time point;

and the transmission module is used for transmitting the control signal to the receiver of the control signal by means of the response time point.

6. The industrial design system for improving interactive experience according to claim 1, wherein the method for enabling interactive control signals between the control signal bidirectional transfer module i and the control signal bidirectional transfer module ii, which is operated on the receiver of the control signals, comprises:

SA-1, affirming a response time point, wherein the response time point is used for commanding a transmitter of the control signal to transmit the control signal to a receiver of the control signal by the response time point;

and SA-2, transmitting the time point of the response to the transmitting party of the control signal.

7. The system as claimed in claim 6, wherein the receiver of the control signal identifies the usage of the current carrier frequency, and further obtains the response time point corresponding to the identified usage of the current carrier frequency by using the preset association between the usage and the response time point;

the responding time point can be a time point, a time period or a plurality of time points;

the response time point has more than one time point;

if the response time point has a plurality of time points, the plurality of time points are consistent with the time point and are not continuous, or the plurality of time points are consistent with the time point and are not continuous;

if the plurality of time points are consistent with the time point discontinuity, the time intervals of the adjacent time points in the plurality of time points are the same, or the time intervals of the adjacent time points in the plurality of time points are different;

the receiver of the control signal can be an affirmed responding time before transmitting the command of requesting to transmit the control signal to the transmitter of the control signal; the secondary signal link can be constructed at the transmitting side of the control signal, and the secondary signal link can be a period from the transmitting side of the control signal linking into the receiving side of the control signal to the transmitting side of the control signal disconnecting from the receiving side of the control signal.

8. The system of claim 6, wherein the method for identifying the usage degree of the carrier frequency comprises identifying the usage degree of the carrier frequency according to formula (1):

Z_j=（1-（1/X））×Z_j-1+Y×（1/X）（1）

here, X is a natural number, which explains the time interval at which the current control signal and the previous control signal are associated; j is a natural number, which indicates that j is the command transmission for obtaining the transmission control signal; z_jThe using degree of the corresponding carrier frequency transmitted by the j secondary command for transmitting the control signal is explained; z₀Is 1; y is NULL or 1;

in the case of a j-1 th pass of a command requesting the transfer of a control signal, if the party transferring the control signal transfers the control signal at the first available response time point, then Y is 1, otherwise Y is NULL.

9. The system of claim 6, wherein the method of how the recipient of the control signal identifies the association between the usage level and the response time point comprises:

SB-1, cutting the time distance corresponding to the carrier frequency for transmitting the control signal into different time periods, wherein the time periods have more than one time point;

SB-2, identifying the correlation degree between the time period and the use degree;

here, the larger the size of the degree of use, the larger the amount of time points that are present in the corresponding period and are not the same, and the intervals between the time points are intermittent; the smaller the usage degree is, the smaller the amount of time points in the corresponding time period is;

where S is a natural number greater than zero;

in addition, the acquired subintervals are serialized; here, the smaller the amount of the time point of response, the earlier the sequence thereof; aiming at the consistent number of the response time points, the smaller the time interval between the response time points is, the earlier the sequence is;

SB-3, serializing the utilization by virtue of its size going from low to high, i.e. the smaller the value of the utilization, the earlier its sequence;

SB-4, by virtue of the sequence, identifying the degree of association between the different sub-ranges and the degree of usage;

packaging the response time point in a command requiring to transmit a control signal and transmitting the command to a transmitter of the control signal; or, the response time point is transmitted to the transmitting side of the control signal through a second command.

10. The industrial design system for improving interactive experience according to claim 6, wherein the method for enabling interactive control signals between the control signal bidirectional transfer module I and the control signal bidirectional transfer module II operates on the transfer side of the control signals, and comprises:

SC-1, a response time point transmitted by the receiver of the received control signal, wherein the response time point is used for commanding the transmitter of the control signal to transmit the control signal to the receiver of the control signal by the response time point;

SC-2, by means of the response timing, transmits a control signal to a recipient of the control signal.

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