CN111076355A

CN111076355A - Voice wake-up instruction processing method, device, terminal and storage medium

Info

Publication number: CN111076355A
Application number: CN201911305401.7A
Authority: CN
Inventors: 陈凯
Original assignee: Aux Air Conditioning Co Ltd; Ningbo Aux Electric Co Ltd
Current assignee: Aux Air Conditioning Co Ltd; Ningbo Aux Electric Co Ltd
Priority date: 2019-12-17
Filing date: 2019-12-17
Publication date: 2020-04-28
Anticipated expiration: 2039-12-17
Also published as: CN111076355B

Abstract

The embodiment of the invention provides a voice wake-up instruction processing method, a device, a terminal and a storage medium, wherein the method comprises the following steps: when the terminal is in a non-awakening state, a voice awakening instruction is received, and then the comprehensive state of the terminal is obtained; if the comprehensive state is the first state, calling a first voice awakening engine to respond to the voice awakening instruction; if the comprehensive state is the second state, calling a second voice awakening engine to respond to the voice awakening instruction; and the use probability of the first state is less than that of the second state, and the response sensitivity of the first voice wake-up engine is less than that of the second voice wake-up engine. The embodiment of the invention reduces the perception of the user on the false awakening and improves the use experience of the user.

Description

Voice wake-up instruction processing method, device, terminal and storage medium

Technical Field

The embodiment of the invention relates to the technical field of communication, in particular to a voice wake-up instruction processing method, a voice wake-up instruction processing device, a terminal and a storage medium.

Background

Currently, terminals with voice recognition capability, such as air conditioners, in the market mainly adopt a prompt tone and/or an indicator light to feed back to a user that the terminal enters an awakening state. But limited by the accuracy of the voice wake-up engine at the present stage, false wake-up cannot be solved technically. The interactive experience of the user is better by adopting the prompt tone than by adopting the indicator lamp, because the user can control the terminal through the prompt tone under the condition of back to the terminal or other scenes that the terminal cannot be observed.

However, it has been found that the prior art has at least the following drawbacks: when the user is awoken by mistake, the prompting sound has stronger perceptibility to the user and is easier to be found by the user, namely, the user has stronger perception to the awoken by mistake, and the use experience of the user is influenced.

Disclosure of Invention

The embodiment of the invention provides a voice awakening instruction processing method, a voice awakening instruction processing device, a terminal and a storage medium, so that the perception of a user on mistaken awakening is reduced, and the use experience of the user is improved.

In a first aspect, an embodiment of the present invention provides a method for processing a voice wake-up instruction, where the method includes:

when the terminal is in a non-awakening state, receiving a voice awakening instruction, and acquiring a comprehensive state of the terminal;

if the comprehensive state is the first state, calling a first voice awakening engine to respond to the voice awakening instruction;

if the comprehensive state is a second state, calling a second voice awakening engine to respond to the voice awakening instruction;

wherein the probability of use of the first state is less than the probability of use of the second state, and the response sensitivity of the first voice wake-up engine is less than the response sensitivity of the second voice wake-up engine.

According to the embodiment of the invention, the corresponding voice awakening engine is called according to the state corresponding to the comprehensive state of the terminal, namely, if the comprehensive state of the terminal is the first state, the first voice awakening engine is called to respond to the voice awakening instruction, and if the comprehensive state of the terminal is the second state, the second voice awakening engine is called to respond to the voice awakening instruction, the response sensitivity of the first voice awakening engine is smaller than that of the second voice awakening engine, so that the perception for mistaken awakening is reduced, and the use experience of a user is improved.

Further, when the terminal is in the non-wake-up state and receives the voice wake-up instruction, acquiring the comprehensive state of the terminal, including:

when a terminal is in a non-awakening state and a voice awakening instruction is received, acquiring a comprehensive state identifier of the terminal;

and determining the comprehensive state of the terminal according to the comprehensive state identifier.

The embodiment of the invention can reduce the data processing amount by determining the comprehensive state of the terminal according to the comprehensive state identifier of the terminal.

Further, the determining the comprehensive state of the terminal according to the comprehensive state identifier includes:

if the comprehensive state identifier is a sleep state identifier, determining that the comprehensive state of the terminal is a sleep state;

if the comprehensive state identifier is a first user state identifier, determining that the comprehensive state of the terminal is a first user state, wherein the first user state identifier indicates that the terminal is in a non-sleep state and no user exists in a preset range from the terminal;

if the comprehensive state identifier is a second user state identifier, determining that the comprehensive state of the terminal is a second user state, wherein the second user state identifier represents that the terminal is in a non-sleep state and users exist in a preset range from the terminal;

if the comprehensive state identifier is a first using state identifier, determining that the comprehensive state of the terminal is a first using state, wherein the first using state identifier indicates that the terminal is in a non-sleeping state, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal meets a preset indoor environment parameter condition;

and if the comprehensive state identifier is a second using state identifier, determining that the comprehensive state of the terminal is a second using state, wherein the second using state identifier indicates that the terminal is in a non-sleeping state, no user exists in a preset range from the terminal, and the indoor environment parameter of the terminal does not meet the preset indoor environment parameter condition.

Further, if the integrated state is the first state, invoking a first voice wake-up engine to respond to the voice wake-up instruction includes:

if the comprehensive state is a sleep state, determining that the comprehensive state is a first state, and calling a first voice awakening engine to respond to the voice awakening instruction;

if the comprehensive state is the first user state, determining that the comprehensive state is the first state, and calling a first voice awakening engine to respond to the voice awakening instruction;

and if the comprehensive state is the first using state, determining that the comprehensive state is the first state, and calling a first voice awakening engine to respond to the voice awakening instruction.

Further, if the integrated state is the second state, invoking a second voice wake-up engine to respond to the voice wake-up instruction includes:

if the comprehensive state is the second user state, determining that the comprehensive state is the second state, and calling a second voice awakening engine to respond to the voice awakening instruction;

and if the comprehensive state of the terminal is the second using state, determining that the comprehensive state belongs to the second state, and calling a second voice awakening engine to respond to the voice awakening instruction.

Further, before the receiving the voice wake-up command and acquiring the comprehensive state identifier of the terminal when the terminal is in the non-wake-up state, the method further includes:

acquiring a comprehensive mode of a terminal;

if the comprehensive mode is a sleep mode, determining that the comprehensive state identifier of the terminal is a sleep state identifier;

if the comprehensive mode is a first user mode, determining that the comprehensive state identifier of the terminal is a first user state identifier, wherein the first user mode indicates that the terminal is in a non-sleep mode and no user exists in a preset range from the terminal;

if the comprehensive mode is a second user mode, determining that the comprehensive state identifier of the terminal is a second user state identifier, wherein the second user mode represents that the terminal is in a non-sleep mode and users exist in a preset range from the terminal;

if the comprehensive mode is a first use mode, determining that the comprehensive state identifier of the terminal is a first use state identifier, wherein the first use mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal meets a preset indoor environment parameter condition;

and if the comprehensive mode is a second use mode, determining that the comprehensive state identifier of the terminal is a second use state identifier, wherein the second use mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal does not meet the preset indoor environment parameter condition.

acquiring a mobile parameter of a user;

if the mobile parameters meet preset mobile parameter conditions, determining that a user exists in a preset range from the terminal;

and if the mobile parameter does not meet the preset mobile parameter condition, determining that no user exists in the preset range from the terminal.

Further, the acquiring the mobile parameter of the user includes:

movement parameters of the user collected by a sensor with a function of monitoring the movement state of the user are obtained.

Further, the terminal is an air conditioner, and the indoor environment parameters of the air conditioner include at least one of the following: the air conditioner comprises an indoor environment temperature of the air conditioner, an indoor environment humidity of the air conditioner, a target gas concentration of an indoor environment where the air conditioner is located and harmful gases of the indoor environment where the air conditioner is located;

the indoor environment parameter of the air conditioner satisfies the preset indoor environment parameter condition, including:

if the indoor environment parameter of the air conditioner meets the following contents, determining that the indoor environment parameter of the air conditioner meets a preset indoor environment parameter condition:

the indoor environment temperature of the air conditioner is greater than or equal to a first indoor environment temperature threshold and less than or equal to a second indoor environment temperature threshold, and the first indoor environment temperature threshold is less than the second indoor environment temperature threshold;

the indoor environment humidity of the air conditioner is less than or equal to an indoor environment humidity threshold value;

the target gas concentration of the indoor environment where the air conditioner is located is less than or equal to a target gas concentration threshold value;

the indoor environment where the air conditioner is located does not have the harmful gas;

if the indoor environment parameter of the air conditioner meets at least one of the following conditions, determining that the indoor environment parameter of the air conditioner does not meet a preset indoor environment parameter condition:

the indoor ambient temperature of the air conditioner is greater than the second indoor ambient temperature threshold value;

the indoor ambient temperature of the air conditioner is less than the first indoor ambient temperature threshold;

the indoor environment humidity of the air conditioner is greater than the indoor environment humidity threshold value;

the target gas concentration of the indoor environment where the air conditioner is located is greater than the target gas concentration threshold;

the harmful gas exists in the indoor environment where the air conditioner is located.

In a second aspect, an embodiment of the present invention further provides a device for processing a voice wake-up instruction, where the device includes:

the comprehensive state acquisition module is used for acquiring the comprehensive state of the terminal when the terminal is in a non-awakening state and a voice awakening instruction is received;

the first voice awakening engine calling module is used for calling the first voice awakening engine to respond to the voice awakening instruction if the comprehensive state is the first state;

the second voice awakening engine calling module is used for calling a second voice awakening engine to respond to the voice awakening instruction if the comprehensive state is the second state;

In a third aspect, an embodiment of the present invention further provides a terminal, where the terminal includes:

one or more processors;

a memory for storing one or more programs;

when executed by the one or more processors, cause the one or more processors to implement a method according to the first aspect of an embodiment of the present invention;

the voice recognition module comprises a first voice awakening engine and a second voice awakening engine, and the first voice awakening engine is used for responding to a voice awakening instruction when the processor determines that the comprehensive state of the terminal belongs to a first state; the second voice wake-up engine is used for responding to the voice wake-up instruction when the processor determines that the comprehensive state of the terminal belongs to the second state.

In a fourth aspect, the present invention further provides a computer-readable storage medium, on which a computer program is stored, which when executed by a processor implements the method according to the first aspect of the present invention.

Drawings

Fig. 1 is a flowchart of a voice wake-up instruction processing method according to a first embodiment of the present invention;

fig. 2 is a schematic structural diagram of a voice wake-up instruction processing apparatus according to a second embodiment of the present invention;

fig. 3 is a schematic structural diagram of a terminal in a third embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention, and that the embodiments and features of the embodiments may be combined with each other without conflict. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

The reason why the perception of the user for the false wake-up is strong in the conventional technology is that: when the terminal is in a non-awakening state, no matter what comprehensive state the terminal is currently in, after the terminal receives the voice awakening instruction, the same voice awakening engine is called to respond to the voice awakening instruction, and the response sensitivity of the voice awakening engine to different comprehensive states is the same. The integrated state of the terminal may include an operation state of the terminal and a surrounding state of the terminal. The operation state may be understood as a state corresponding to an operation mode of the terminal. The run state may include a sleep state and a non-sleep state. The surrounding state may be understood to include the presence or absence of a user within a predetermined range from the terminal, and the indoor environment state in which the terminal is located. The indoor environment state in which the terminal is located may be represented by an indoor environment parameter. This makes it undesirable for the user using the terminal to respond to the voice wake-up command in some integrated states to wake up the terminal. If the voice wakeup engine wakes up the terminal in response to the voice wakeup command in the above case, such wake-up may be interpreted as a false wake-up of the terminal. It can be appreciated that when the user does not want to wake up the terminal originally, if the terminal is woken up, i.e. the terminal is mistakenly woken up, the user's perception of such a mistaken wake-up is strong.

Based on the above, in order to reduce the user's perception of false arousal, the following aspects may be considered: the false wake-up of the terminal is that the user does not actually want to wake up the terminal, but the voice wake-up engine has the same response sensitivity to different integrated states, so the voice wake-up engine can respond to different integrated states. Based on the current probability of using the terminal by the user, i.e. the size of the usage probability, the integrated states in which the terminal is located can be divided, the integrated state with relatively low usage probability can be called as a first state, and the integrated state with relatively high usage probability can be called as a second state, i.e. the usage probability of the first state is smaller than that of the second state. It can be understood that, if the terminal is awoken by mistake, this situation may indicate that the probability of using the terminal by the user is small, and based on this, the integrated state corresponding to the terminal that is awoken by mistake may be divided to belong to the first state, that is, the integrated state corresponding to the terminal that is awoken by mistake belongs to the first state. Accordingly, the integrated states other than the integrated state corresponding to the terminal that may be erroneously awakened may be classified as belonging to the second state, i.e., the integrated states other than the integrated state corresponding to the terminal that may be erroneously awakened belong to the second state. Just as the response sensitivity of the voice awakening engine to different comprehensive states is the same, the terminal is caused to be awakened by mistake, so that the voice awakening engine with different response sensitivities can be called to different comprehensive states, the terminal is prevented from being awakened by mistake as far as possible, the perception of the user on the mistaken awakening is reduced, and the use experience of the user is improved. I.e. if it is determined that the integrated state of the terminal belongs to the first state, it may be considered to invoke a voice wake-up engine with a relatively low response sensitivity, since the response sensitivity of such a voice wake-up engine is low, and therefore the probability that the terminal is woken up will be reduced, which corresponds exactly to the actual requirements of the user. If the comprehensive state of the terminal is determined to belong to the second state, a voice wake-up engine with relatively high response sensitivity can be considered to be called, the response to the voice wake-up instruction can be quickly and accurately realized due to the high response sensitivity of the voice wake-up engine, and if the comprehensive state of the terminal belongs to the second state, the probability that the user uses the terminal is high, so that the actual requirement of the user can be realized by calling the voice wake-up engine with relatively high response sensitivity, namely the actual requirement of the user is exactly met.

Based on the above, it is considered that the voice wake-up engines with different response sensitivities are set in the voice recognition module, and then which voice wake-up engine to call to respond to the voice wake-up instruction can be determined according to the comprehensive state of the terminal. The voice wake-up engine with relatively low response sensitivity described above may be referred to herein as a first voice wake-up engine and the voice wake-up engine with relatively high response sensitivity described above may be referred to herein as a second voice wake-up engine. I.e. the response sensitivity of the first voice wake-up engine is smaller than the response sensitivity of the second voice wake-up engine. That is, it is considered that the first voice wake-up engine and the second voice wake-up engine are set in the voice recognition module, wherein the response sensitivity of the first voice wake-up engine is smaller than the response sensitivity of the second voice wake-up engine. And determining whether to call the first voice awakening engine or the second voice awakening engine according to the comprehensive state of the terminal so as to respond to the voice awakening instruction. The following description will be made with reference to specific examples.

Example one

Fig. 1 is a flowchart of a voice wake-up instruction processing method according to an embodiment of the present invention, which is applicable to reducing the user's perception of false wake-up and improving the user experience, and the method may be executed by a voice wake-up instruction processing device, which may be implemented in a software and/or hardware manner, and may be configured in a terminal. Such as air conditioners, smart televisions, and the like. As shown in fig. 1, the method specifically includes the following steps:

and 110, when the terminal is in a non-awakening state and receives a voice awakening instruction, acquiring the comprehensive state of the terminal.

In the embodiment of the present invention, when the terminal is in the non-awake state, the voice wake-up instruction may be understood as a voice instruction for waking up the terminal. The voice wake-up instruction is typically issued by the user using the terminal. As can be seen from the above, the integrated state of the terminal can be understood to include the operation state of the terminal and the surrounding state of the terminal. The operation state may be understood as a state corresponding to an operation mode of the terminal. The run state may include a sleep state and a non-sleep state. The surrounding state may be understood to include the presence or absence of a user within a predetermined range from the terminal, and the indoor environment state in which the terminal is located. The indoor environment state in which the terminal is located may be represented by an indoor environment parameter.

When the terminal is in a non-awakening state, the terminal receives the voice awakening instruction, the comprehensive state of the terminal can be obtained, and then the voice awakening engine can be determined to be called to respond to the voice awakening instruction according to the comprehensive state of the terminal. When the terminal is in the non-wake-up state, the terminal receives the voice wake-up instruction, and then the comprehensive state of the terminal can be obtained, which can be understood as follows: the comprehensive state of the terminal can be determined according to the comprehensive state identification for the comprehensive state identification of the terminal in advance. That is, when the terminal is in the non-wake-up state, the terminal receives the voice wake-up instruction, and the comprehensive state identifier of the terminal can be obtained. And determining the comprehensive state of the terminal according to the comprehensive state identifier.

Step 120, if the integrated state is the first state, a first voice wake-up engine is invoked to respond to the voice wake-up command.

Step 130, if the integrated state is the second state, a second voice wake-up engine is called to respond to the voice wake-up instruction.

And the use probability of the first state is less than that of the second state, and the response sensitivity of the first voice wake-up engine is less than that of the second voice wake-up engine.

In the embodiment of the present invention, as can be seen from the above description, the integrated state of the terminal can be divided into the first state and the second state according to the current usage probability of the terminal. Wherein the probability of use of the first state is less than the probability of use of the second state. That is, if it is determined that the probability that the terminal is currently used is relatively small according to the integrated state of the terminal, the integrated state of the terminal may be classified as belonging to the first state. If it is determined that the probability that the terminal is currently used is relatively large according to the integrated state of the terminal, the integrated state of the terminal may be classified as belonging to the second state. The usage probability may be used to account for the probability that the terminal is currently being used. The voice recognition module can be provided with two voice wake-up engines with different response sensitivities, namely a first voice wake-up engine and a second voice wake-up engine. Wherein the response sensitivity of the first voice wake-up engine may be less than the response sensitivity of the second voice wake-up engine. The first voice wake-up engine may be configured to respond to the voice wake-up command to wake up the terminal when the integrated state of the terminal belongs to the first state. The second voice wake-up engine may be configured to respond to the voice wake-up command to wake up the terminal when the integrated state of the terminal belongs to the second state.

The reason why the above-described usage probability of the terminal can be expressed based on the integrated state of the terminal is that: as can be seen from the foregoing, the comprehensive state of the terminal may include an operating state of the terminal and a surrounding state of the terminal, and the operating state may be understood as a state corresponding to an operating mode of the terminal. The run state may include a sleep state and a non-sleep state. The surrounding state may be understood to include whether a user is present within a preset range from the terminal, and an indoor environment state in which the terminal is located. For the operation state of the terminal, if the user does not need to use the terminal currently, the operation mode of the user can be set to the sleep mode, and correspondingly, the operation state of the terminal is the sleep state. That is, if the operation state of the terminal is the sleep state, it may indicate that the probability that the terminal is currently used is relatively low. On the contrary, if the user needs to use the terminal currently, the operation mode of the user can be set to be the non-sleep mode, and correspondingly, the operation state of the terminal is the non-sleep state. That is, if the operation state of the terminal is the non-sleep state, it may indicate that the probability that the terminal is currently used is relatively high. Of course, in this case, whether the terminal needs to be used or not may be determined in combination with other conditions. The above shows that the operation state of the terminal can reflect the current use probability of the terminal to a certain extent. Regarding whether a user exists within a preset range from the terminal, generally, if no user exists within the preset range from the terminal, it may be said that the probability that the terminal is currently used is relatively low. That is, if there is no user within a preset range from the terminal, it may be said that the probability that the terminal is currently used is relatively low. If there is a user within a preset range from the terminal, it can be said that the probability that the terminal is currently used is relatively high. That is, if there is a user within a preset range from the terminal, it may indicate that the probability that the terminal is currently used is relatively high. This is because whether the terminal is normally used or not is controlled by the user. If there is no user within a preset range from the terminal, the probability that the terminal is currently used is greatly reduced. The presence of the user in the preset range from the terminal may include the following two cases: firstly, a user exists in a preset range from a terminal, but the user may not move; secondly, a user exists in a preset range from the terminal, and the user moves. The fact that no user exists in the preset range from the terminal can be understood as that no user exists in the preset range from the terminal. The above shows that whether the user exists in the preset range from the terminal can reflect the current used probability of the terminal to a certain extent. Of course, in this case, whether the terminal needs to be used or not may be determined in combination with other conditions. For the indoor environment state of the terminal, the indoor environment state of the terminal may be represented by an indoor environment parameter, and if the terminal is an air conditioner, the indoor environment parameter of the terminal may include at least one of an indoor environment temperature of the terminal, an indoor environment humidity of the terminal, a target gas concentration of the indoor environment of the terminal, a harmful gas of the indoor environment of the terminal, and the like. It can be seen that if the indoor ambient temperature is too high or too low, the probability of the user using the air conditioner will increase to achieve warming or cooling. In contrast, if the indoor ambient temperature is within the preset temperature range, the probability of the user using the air conditioner will be reduced. If the indoor ambient humidity is too high, the probability of the user using the air conditioner will also increase to achieve a reduced humidity. Accordingly, if the indoor ambient humidity is within the preset humidity range, the probability of the user using the air conditioner will also be reduced. If the target gas concentration in the indoor environment is too high, the probability of the user using the air conditioner will also increase to achieve a reduction in the target gas concentration by blowing air or the like. The target gas may be carbon dioxide or the like. Conversely, if the target gas concentration of the indoor environment is less than or equal to the target gas concentration threshold, the probability of the user using the air conditioner will also decrease. If harmful gas exists in the indoor environment, the probability of using the air conditioner by a user is increased, so that the harmful gas is reduced by exhausting air and the like. Conversely, if the indoor environment does not have harmful gases, the probability of the user using the air conditioner will also be reduced. The above shows that the indoor environment state where the terminal is located can reflect the current probability of being used of the terminal to a certain extent. Of course, in this case, whether the terminal needs to be used or not may be determined in combination with other conditions. In addition, for different terminals, the corresponding environment parameters may be different, and may be specifically set according to actual situations, which is not specifically limited herein.

Based on the above, since the operation state of the terminal in the integrated state of the terminal, whether the user exists within the preset range from the terminal, and the indoor environment state where the terminal is located can reflect the current usage probability of the terminal to a certain extent, the usage probability of the terminal can be expressed based on the integrated state of the terminal.

After the comprehensive state of the terminal is obtained, whether the comprehensive state of the terminal belongs to the first state or the second state can be determined. If the terminal determines that the comprehensive state of the terminal belongs to the first state, the voice awakening engine with relatively low response sensitivity can be called, namely the first voice awakening engine can be called to respond to the voice awakening instruction to awaken the terminal. And if the terminal determines that the comprehensive state of the terminal belongs to the second state, the voice awakening engine with relatively high response sensitivity can be called, namely the second voice awakening engine can be called to respond to the voice awakening instruction to awaken the terminal.

According to the technical scheme, the corresponding voice awakening engine is called according to the state corresponding to the comprehensive state of the terminal, namely if the comprehensive state of the terminal is the first state, the first voice awakening engine is called to respond to the voice awakening instruction, if the comprehensive state of the terminal is the second state, the second voice awakening engine is called to respond to the voice awakening instruction, the response sensitivity of the first voice awakening engine is smaller than that of the second voice awakening engine, the perception for mistaken awakening is reduced, and the use experience of a user is improved.

Optionally, on the basis of the above technical solution, when the terminal is in a non-wakeup state and receives the voice wakeup instruction, the method obtains the comprehensive state of the terminal, and specifically may include: and when the terminal is in a non-awakening state and receives the voice awakening instruction, acquiring the comprehensive state identifier of the terminal. And determining the comprehensive state of the terminal according to the comprehensive state identifier.

In an embodiment of the present invention, the integrated state identifier may be used to identify the integrated state in which the terminal is located. The terminal can be identified in advance in a comprehensive state, so that the comprehensive state of the terminal can be determined subsequently according to the comprehensive state identification of the terminal. The integrated state identifier may include a sleep state identifier, a first user state identifier, a second user state identifier, a first usage state identifier, and a second usage state identifier.

The comprehensive state identifier of the terminal can be determined in the following way: the integrated mode of the terminal can be obtained. The integrated mode may include a sleep mode, a first user mode, a second user mode, a first usage mode, and a second usage mode. The first user mode may indicate that the integrated mode of the terminal is a non-sleep mode and that there is no user within a preset range from the terminal. The second user mode may indicate that the integrated mode of the terminal is the non-sleep mode and that a user exists within a preset range from the terminal. The first usage mode may indicate that the integrated mode of the terminal is a non-sleep mode, that a user is present within a preset range from the terminal, and that the indoor environment parameter of the terminal satisfies a preset indoor environment parameter condition. The second usage mode may indicate that the integrated mode of the terminal is a non-sleep mode, that no user exists within a preset range from the terminal, and that the indoor environment parameter of the terminal does not satisfy a preset indoor environment parameter condition.

Based on this, the terminal may determine that the integrated state flag of the terminal is a sleep state flag if it is determined that the integrated mode is the sleep mode. The terminal may determine that the integrated state identifier of the terminal is the first user state identifier if it is determined that the integrated mode is the first user mode. And if the terminal determines that the integrated mode is the second user mode, determining that the integrated state identifier of the terminal is the second user state identifier. The terminal may determine that the integrated state identifier of the terminal is the first usage state identifier if it is determined that the integrated mode is the first usage mode. The terminal may determine that the integrated state identifier of the terminal is the second usage state identifier if it is determined that the integrated mode is the second usage mode.

The comprehensive state of the terminal is determined according to the comprehensive state identifier of the terminal, so that the data processing amount can be reduced.

Optionally, on the basis of the above technical solution, determining the comprehensive state of the terminal according to the comprehensive state identifier may specifically include: and if the comprehensive state identifier is the sleep state identifier, determining that the comprehensive state of the terminal is the sleep state. And if the comprehensive state identifier is the first user state identifier, determining that the comprehensive state of the terminal is the first user state, wherein the first user state identifier represents that the terminal is in a non-sleep state and no user exists in a preset range from the terminal. And if the comprehensive state identifier is a second user state identifier, determining that the comprehensive state of the terminal is a second user state, wherein the second user state identifier represents that the terminal is in a non-sleep state and a user exists in a preset range from the terminal. And if the comprehensive state identifier is the first using state identifier, determining that the comprehensive state of the terminal is the first using state, wherein the first using state identifier indicates that the terminal is in a non-sleeping state, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal meets the preset indoor environment parameter condition. And if the comprehensive state identifier is a second use state identifier, determining that the comprehensive state of the terminal is a second use state, wherein the second use state identifier indicates that the terminal is in a non-sleep state, no user exists in a preset range from the terminal, and the indoor environment parameters of the terminal do not meet the preset indoor environment parameter conditions.

In an embodiment of the present invention, the integrated status identifier may include a sleep status identifier, a first user status identifier, a second user status identifier, a first usage status identifier, and a second usage status identifier. The sleep state identifier may be used to indicate that the terminal is currently in a sleep state. The sleep state may include normal sleep, self-set sleep, comfortable sleep, and the like. The first user state identifier may indicate that the terminal is in a non-sleep state, and no user exists within a preset range from the terminal. The non-sleep state may include states other than a sleep state. The second user state identifier may indicate that the terminal is in a non-sleep state, and a user exists within a preset range from the terminal. The presence of the user in the preset range from the terminal may include the following two cases: firstly, a user exists in a preset range from a terminal, but the user may not move; secondly, a user exists in a preset range from the terminal, and the user moves. The first use state identifier may indicate that the terminal is in a non-sleep state, a user is present within a preset range from the terminal, and the indoor environment parameter of the terminal satisfies a preset indoor environment parameter condition. The second use state identifier may indicate that the terminal is in a non-sleep state, no user exists within a preset range from the terminal, and the indoor environment parameter of the terminal does not satisfy a preset indoor environment parameter condition.

The preset indoor environment parameter condition may be used as a condition for determining whether the indoor environment parameter satisfies a requirement that the probability of use of the terminal is relatively small. The terminal can comprise an air conditioner, an intelligent television and the like. Indoor environment parameters of different terminals may be different, and correspondingly, preset indoor environment parameter conditions of different terminals may be different. The specific setting may be performed according to actual conditions, and is not particularly limited herein. Optionally, if the terminal is an air conditioner, the indoor environment parameter of the terminal may include at least one of: the air conditioner comprises an indoor environment temperature of the air conditioner, an indoor environment humidity of the air conditioner, a target gas concentration of an indoor environment where the air conditioner is located and harmful gases of the indoor environment where the air conditioner is located. Accordingly, the pre-indoor environment parameter may include at least one of: the air conditioner comprises an indoor environment temperature threshold of the air conditioner, an indoor environment humidity threshold of the air conditioner, a target gas concentration threshold of an indoor environment where the air conditioner is located, and the presence or absence of harmful gas in the indoor environment where the air conditioner is located.

Based on this, if the integrated state flag is a sleep state flag, it may be determined that the integrated state of the terminal is a sleep state. If the integrated state identifier is the first user state identifier, it may be determined that the integrated state of the terminal is the first user state. If the integrated state identifier is the second user state identifier, it may be determined that the integrated state of the terminal is the second user state. If the integrated state identifier is the first use state identifier, it may be determined that the integrated state of the terminal is the first use state. If the integrated state identifier is the second use state identifier, it may be determined that the integrated state of the terminal is the second use state.

It should be noted that the sleep state and the non-sleep state described above can be understood as being directed to the operation state of the terminal. Whether or not the user exists within a preset range from the terminal may be understood as being directed to the surrounding state of the terminal. Whether the indoor environment parameter of the terminal meets the preset indoor environment parameter condition or not can be understood as being specific to the surrounding state of the terminal, and more specifically to the indoor environment state where the terminal is located.

In addition, the content indicated by each integrated status flag may be determined according to a preset status priority. The sleep state can be generally considered, and the probability that the terminal is not used is the largest, i.e., the sleep state has the largest impact on determining whether the terminal is used. Based on this, the state priority corresponding to the sleep state can be set to be the highest. If the terminal is in the non-sleep state, whether the influence of the user on whether the terminal is used is larger than the influence of whether the indoor environment parameters of the terminal meet the preset indoor environment parameter conditions on whether the terminal is used exists in the preset range of the terminal. Based on the method, whether the indoor environment parameter with the priority higher than that of the terminal corresponding to the user in the preset range from the terminal meets the preset indoor environment parameter condition or not can be set. Based on the above, the content included in the sleep state identifier, the first user state identifier, the second user state identifier, the first usage state identifier, and the second usage state identifier may be determined.

Optionally, on the basis of the above technical solution, if the integrated state is the first state, invoking the first voice wake-up engine to respond to the voice wake-up instruction may specifically include: and if the comprehensive state is the sleep state, determining that the comprehensive state is the first state, and calling the first voice wake-up engine to respond to the voice wake-up instruction. And if the comprehensive state is the first user state, determining that the comprehensive state is the first state, and calling the first voice awakening engine to respond to the voice awakening instruction. And if the comprehensive state is the first using state, determining that the comprehensive state is the first state, and calling the first voice wake-up engine to respond to the voice wake-up instruction.

In an embodiment of the present invention, since the first state may be a state in which a probability that the terminal is currently used is relatively low, and the sleep state, the first user state, and the first use state may each represent a state in which a probability that the terminal is currently used is relatively low, the sleep state, the first user state, and the first use state may be determined as the first state. I.e. the first state may comprise a sleep state, a first user state and a first use state. Accordingly, the first voice wake engine may be invoked in response to the voice wake instruction. That is, if the integrated state is the sleep state, the integrated state may be determined to be the first state and the first voice wake engine may be invoked in response to the voice wake instruction. If the integrated state is the first user state, the integrated state may be determined to be the first state and the first voice wake engine may be invoked in response to the voice wake instruction. If the integrated state is the first use state, the integrated state may be determined to be the first state and the first voice wake engine may be invoked in response to the voice wake instruction.

Optionally, on the basis of the above technical solution, if the integrated state is the second state, the second voice wake-up engine is called to respond to the voice wake-up instruction, which may specifically include: and if the comprehensive state is the second user state, determining that the comprehensive state is the second state, and calling a second voice awakening engine to respond to the voice awakening instruction. And if the comprehensive state of the terminal is the second using state, determining that the comprehensive state belongs to the second state, and calling a second voice awakening engine to respond to the voice awakening instruction.

In an embodiment of the present invention, since the second state may be a state in which the probability that the terminal is currently used is relatively high, and both the second user state and the second use state may represent a state in which the probability that the terminal is currently used is relatively high, the second user state and the second use state may be determined as the second state. I.e. the second state may comprise a second user state and a second use state. Accordingly, a second voice wake engine may be invoked in response to the voice wake instruction. That is, if the integrated state is the second user state, the integrated state may be determined to be the second state and the second voice wake-up engine may be invoked in response to the voice wake-up command. If the integrated state of the terminal is the second use state, it may be determined that the integrated state belongs to the second state and a second voice wake-up engine may be invoked in response to the voice wake-up command.

Optionally, on the basis of the above technical solution, before the terminal receives the voice wake-up instruction when the terminal is in the non-wake-up state and acquires the comprehensive state identifier of the terminal, the method may further include: and acquiring a comprehensive mode of the terminal. And if the integrated mode is the sleep mode, determining that the integrated state identifier of the terminal is the sleep state identifier. And if the integrated mode is the first user mode, determining that the integrated state identifier of the terminal is the first user state identifier, wherein the first user mode indicates that the terminal is in a non-sleep mode and no user exists in a preset range from the terminal. And if the comprehensive mode is the second user mode, determining that the comprehensive state identifier of the terminal is the second user state identifier, wherein the second user mode indicates that the terminal is in a non-sleep mode and a user exists in a preset range from the terminal. And if the comprehensive mode is the first use mode, determining that the comprehensive state identifier of the terminal is the first use state identifier, wherein the first use mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal meets the preset indoor environment parameter condition. And if the comprehensive mode is the second use mode, determining that the comprehensive state identifier of the terminal is the second use state identifier, wherein the second use mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal does not meet the preset indoor environment parameter condition.

In the embodiment of the invention, the comprehensive state identifier of the terminal can be determined according to the comprehensive mode of the terminal. The integrated mode may include a sleep mode, a first user mode, a second user mode, a first usage mode, and a second usage mode. The first user mode may indicate that the terminal is in a non-sleep mode, and no user exists within a preset range from the terminal. The second user mode may be expressed as a non-sleep mode of the terminal, and a user exists within a preset range from the terminal. The first usage mode may indicate that the terminal is in a non-sleep mode, that a user is present within a preset range from the terminal, and that the indoor environment parameter of the terminal satisfies a preset indoor environment parameter condition. The second usage mode may indicate that the terminal is in a non-sleep mode, that a user is present within a preset range from the terminal, and that the indoor environment parameter of the terminal does not satisfy a preset indoor environment parameter condition.

It should be noted that the above-mentioned sleep mode and non-sleep mode can be understood as the operation modes of the terminal. The sleep mode and the non-sleep mode may be determined according to a setting instruction input by a user. Whether a user exists in a preset range from the terminal or not can be acquired through a sensor with a function of monitoring the moving state of the user. The indoor environment parameters of the terminal can be acquired through the corresponding sensors of the indoor environment parameters.

It should be further noted that the indoor environment parameters for the terminal may be obtained before the voice wake-up instruction is received, and whether the indoor environment parameters of the terminal meet the preset indoor environment parameter conditions is determined. And after receiving the voice awakening instruction, acquiring the indoor environment parameters in real time when whether the indoor environment parameters of the terminal meet the preset indoor environment parameter conditions needs to be determined. The specific setting may be performed according to actual conditions, and is not particularly limited herein.

Optionally, on the basis of the above technical solution, before the terminal receives the voice wake-up instruction when the terminal is in the non-wake-up state and acquires the comprehensive state identifier of the terminal, the method may further include: and acquiring the mobile parameters of the user. And if the mobile parameters meet the preset mobile parameter conditions, determining that the user exists in the preset range from the terminal. And if the mobile parameter does not meet the preset mobile parameter condition, determining that no user exists in the preset range from the terminal.

In an embodiment of the present invention, the preset moving parameter condition may be used as a basis for determining whether a user exists within a preset range from the terminal. The movement parameter may be used to represent a movement state of the user. The movement state may include moved and not moved. Based on this, if the terminal determines that the movement parameter satisfies the preset movement parameter condition, it may be determined that the user exists within a preset range from the terminal. And if the terminal determines that the movement parameter does not meet the preset movement parameter condition, determining that no user exists in a preset range from the terminal.

Optionally, on the basis of the technical scheme, acquiring the mobile parameter of the user may specifically include: movement parameters of the user collected by a sensor with a function of monitoring the movement state of the user are obtained.

In the embodiment of the present invention, the sensor having the function of monitoring the moving state of the user may include an infrared temperature sensor, a laser, a radar, and the like. The infrared temperature sensor may comprise a thermopile infrared temperature sensor. The terminal can be provided with the sensor. The sensor with the function of monitoring the moving state of the user can acquire the moving parameters of the user. The acquisition period may be set and acquired periodically, and each acquisition period may be set according to an actual situation, which is not specifically limited herein. For example, the acquisition period may be 5 minutes. Correspondingly, if the sensor continuously monitors for 5 minutes and does not detect the movement of the user, the user can be determined to be absent according to the acquired movement parameters. And resetting a timer, namely continuously monitoring for 5 minutes by the sensor to acquire the movement parameters of the user. In addition, it should be noted that the thermopile infrared temperature sensor may collect movement parameters of a user, so that whether the user exists in a preset range from the terminal may be determined according to the movement parameters, and whether the user exists in the preset range from the terminal may also be determined through the heat source.

Optionally, on the basis of the above technical solution, the terminal is an air conditioner, and the indoor environment parameter of the air conditioner includes at least one of the following: the air conditioner comprises an indoor environment temperature of the air conditioner, an indoor environment humidity of the air conditioner, a target gas concentration of an indoor environment where the air conditioner is located and harmful gases of the indoor environment where the air conditioner is located. The indoor environment parameter of the air conditioner satisfies the preset indoor environment parameter condition, and specifically may include: if the indoor environment parameter of the air conditioner meets the following contents, determining that the indoor environment parameter of the air conditioner meets the preset indoor environment parameter condition: the indoor environment temperature of the air conditioner is greater than or equal to a first indoor environment temperature threshold and less than or equal to a second indoor environment temperature threshold, and the first indoor environment temperature threshold is less than the second indoor environment temperature threshold. The indoor environment humidity of the air conditioner is less than or equal to the indoor environment humidity threshold value. The target gas concentration of the indoor environment where the air conditioner is located is less than or equal to the target gas concentration threshold. The air conditioner is in the indoor environment without harmful gas. If the indoor environment parameter of the air conditioner meets at least one of the following conditions, determining that the indoor environment parameter of the air conditioner does not meet the preset indoor environment parameter condition: the indoor ambient temperature of the air conditioner is greater than the second indoor ambient temperature threshold. The indoor ambient temperature of the air conditioner is less than the first indoor ambient temperature threshold. The indoor ambient humidity of the air conditioner is greater than the indoor ambient humidity threshold. The target gas concentration of the indoor environment where the air conditioner is located is greater than the target gas concentration threshold. The indoor environment in which the air conditioner is located has harmful gases.

In an embodiment of the present invention, the terminal may be an air conditioner. The first and second indoor ambient temperature thresholds may be used as a basis for determining whether the indoor ambient temperature of the air conditioner meets a demand. The indoor ambient humidity threshold may be used as a basis for determining whether the indoor ambient temperature of the air conditioner meets a demand. The target gas concentration threshold may be used as a basis for determining whether the target gas concentration of the indoor environment in which the air conditioner is located meets the demand. The first indoor ambient temperature threshold is less than the second indoor ambient temperature threshold. The specific values of the first indoor ambient temperature threshold, the second indoor ambient temperature threshold, the indoor ambient humidity threshold, and the target gas concentration threshold may be set according to actual conditions, and are not limited specifically herein.

If the indoor environment parameter of the air conditioner satisfies the following contents, it may be determined that the indoor environment parameter of the air conditioner satisfies a preset indoor environment parameter condition: if the indoor environment parameter of the air conditioner meets the following contents, determining that the indoor environment parameter of the air conditioner meets the preset indoor environment parameter condition: the indoor environment temperature of the air conditioner is greater than or equal to a first indoor environment temperature threshold and less than or equal to a second indoor environment temperature threshold, and the first indoor environment temperature threshold is less than the second indoor environment temperature threshold. The indoor environment humidity of the air conditioner is less than or equal to the indoor environment humidity threshold value. The target gas concentration of the indoor environment where the air conditioner is located is less than or equal to the target gas concentration threshold. The air conditioner is in the indoor environment without harmful gas.

Determining that the indoor environment parameter of the air conditioner does not satisfy the preset indoor environment parameter condition if the indoor environment parameter of the air conditioner satisfies at least one of: the indoor ambient temperature of the air conditioner is greater than the second indoor ambient temperature threshold. The indoor ambient temperature of the air conditioner is less than the first indoor ambient temperature threshold. The indoor ambient humidity of the air conditioner is greater than the indoor ambient humidity threshold. The target gas concentration of the indoor environment where the air conditioner is located is greater than the target gas concentration threshold. The indoor environment in which the air conditioner is located has harmful gases.

It should be noted that, if the terminal determines that the integrated state is the first user state, it may determine that the integrated state is the first state, and may call the first voice wake-up engine to respond to the voice wake-up instruction, where the first user state identifier may be generated in the following manner: when the terminal is in a non-awakening state, a voice awakening instruction is received, whether a sleep state identifier exists or not can be determined, if the sleep state identifier does not exist, whether a user exists in a preset range from the terminal or not can be determined, and if the user does not exist in the preset range from the terminal, the first user state identifier can be generated. The first usage state identification may be generated by: when the terminal is in a non-awakening state, a voice awakening instruction is received, whether a sleep state identifier exists or not can be determined, if the sleep state identifier does not exist, whether a user exists in a preset range from the terminal or not can be determined, if the user exists in the preset range from the terminal, whether indoor environment parameters of the terminal meet preset indoor environment parameter conditions or not can be determined, and if the indoor environment parameters of the terminal meet the preset indoor environment parameter conditions or not, a first use state identifier can be generated.

Example two

Fig. 2 is a schematic structural diagram of a voice wake-up instruction processing apparatus according to a second embodiment of the present invention, which is applicable to reducing the perception of a user about false wake-up and improving the user experience. Such as air conditioners, smart televisions, and the like. As shown in fig. 2, the apparatus specifically includes:

the comprehensive state obtaining module 210 is configured to obtain a comprehensive state of the terminal when the terminal is in a non-wake-up state and receives the voice wake-up instruction.

The first voice wake-up engine invoking module 220 is configured to invoke the first voice wake-up engine to respond to the voice wake-up command if the integrated state is the first state.

The first voice wake-up engine invoking module 230 is configured to invoke a second voice wake-up engine to respond to the voice wake-up command if the integrated state is the second state.

Optionally, on the basis of the above technical solution, the comprehensive state obtaining module 210 may specifically include:

and the comprehensive state identifier acquisition submodule is used for acquiring the comprehensive state identifier of the terminal when the terminal is in a non-awakening state and receives the voice awakening instruction.

And the comprehensive state acquisition submodule is used for determining the comprehensive state of the terminal according to the comprehensive state identifier.

Optionally, on the basis of the above technical solution, the comprehensive state obtaining sub-module specifically may include:

and the sleep state determining unit is used for determining that the comprehensive state of the terminal is the sleep state if the comprehensive state identifier is the sleep state identifier.

And the first user state determining unit is used for determining that the comprehensive state of the terminal is the first user state if the comprehensive state identifier is the first user state identifier, and the first user state identifier indicates that the terminal is in a non-sleep state and no user exists in a preset range from the terminal.

And the second user state determining unit is used for determining that the comprehensive state of the terminal is the second user state if the comprehensive state identifier is the second user state identifier, and the second user state identifier indicates that the terminal is in a non-sleep state and a user exists in a preset range from the terminal.

The first using state determining unit is used for determining that the comprehensive state of the terminal is the first using state if the comprehensive state identifier is the first using state identifier, the first using state identifier indicates that the terminal is in a non-sleeping state, a user exists in a preset range from the terminal, and the indoor environment parameters of the terminal meet preset indoor environment parameter conditions.

And the second using state determining unit is used for determining that the comprehensive state of the terminal is the second using state if the comprehensive state identifier is the second using state identifier, the second using state identifier indicates that the terminal is in a non-sleeping state, no user exists in a preset range from the terminal, and the indoor environment parameter of the terminal does not meet the preset indoor environment parameter condition.

Optionally, on the basis of the foregoing technical solution, the first voice wake-up engine invoking module 220 may specifically include:

and the first calling sub-module is used for determining that the comprehensive state is the first state if the comprehensive state is the sleep state and calling the first voice awakening engine to respond to the voice awakening instruction.

And the second calling sub-module is used for determining that the comprehensive state is the first state if the comprehensive state is the first user state, and calling the first voice awakening engine to respond to the voice awakening instruction.

And the third calling sub-module is used for determining that the comprehensive state is the first state if the comprehensive state is the first using state and calling the first voice awakening engine to respond to the voice awakening instruction.

Optionally, on the basis of the foregoing technical solution, the second voice wake-up engine invoking module 230 may specifically include:

and the fourth calling sub-module is used for determining that the comprehensive state is the second state and calling the second voice awakening engine to respond to the voice awakening instruction if the comprehensive state is the second user state.

And the fifth calling submodule is used for determining that the comprehensive state belongs to the second state and calling the second voice awakening engine to respond to the voice awakening instruction if the comprehensive state of the terminal is the second using state.

Optionally, on the basis of the above technical solution, the apparatus may further include:

and the comprehensive mode acquisition module is used for acquiring the comprehensive mode of the terminal.

And the sleep state identification determining module is used for determining that the comprehensive state identification of the terminal is the sleep state identification if the comprehensive mode is the sleep mode.

And the first user state identifier determining module is used for determining that the comprehensive state identifier of the terminal is the first user state identifier if the comprehensive mode is the first user mode, and the first user mode indicates that the terminal is in the non-sleep mode and no user exists in a preset range from the terminal.

And the second user state identifier determining module is used for determining that the comprehensive state identifier of the terminal is the second user state identifier if the comprehensive mode is the second user mode, and the second user mode indicates that the terminal is in the non-sleep mode and users exist in a preset range from the terminal.

The first using state identification determining module is used for determining that the comprehensive state identification of the terminal is the first using state identification if the comprehensive mode is the first using mode, the first using mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameters of the terminal meet preset indoor environment parameter conditions.

And the second use state identifier determining module is used for determining that the comprehensive state identifier of the terminal is the second use state identifier if the comprehensive mode is the second use mode, the second use mode indicates that the terminal is in a non-sleep mode, a user exists in a preset range from the terminal, and the indoor environment parameter of the terminal does not meet the preset indoor environment parameter condition.

and the mobile parameter acquisition module is used for acquiring the mobile parameters of the user.

The user existence module is used for determining that a user exists in a preset range from the terminal if the mobile parameter meets a preset mobile parameter condition;

and the user non-existence module is used for determining that no user exists in the preset range from the terminal if the movement parameter does not meet the preset movement parameter condition.

Optionally, on the basis of the above technical solution, the moving parameter obtaining module may specifically include:

and the movement parameter acquisition sub-module is used for acquiring the movement parameters of the user, which are acquired by the sensor with the function of monitoring the movement state of the user.

Optionally, on the basis of the above technical solution, the terminal is an air conditioner, and the indoor environment parameter of the air conditioner includes at least one of the following: the air conditioner comprises an indoor environment temperature of the air conditioner, an indoor environment humidity of the air conditioner, a target gas concentration of an indoor environment where the air conditioner is located and harmful gases of the indoor environment where the air conditioner is located.

The indoor environment parameter of the air conditioner satisfies the preset indoor environment parameter condition, and specifically may include:

if the indoor environment parameter of the air conditioner meets the following contents, determining that the indoor environment parameter of the air conditioner meets the preset indoor environment parameter condition:

the indoor environment temperature of the air conditioner is greater than or equal to a first indoor environment temperature threshold and less than or equal to a second indoor environment temperature threshold, and the first indoor environment temperature threshold is less than the second indoor environment temperature threshold.

The indoor environment humidity of the air conditioner is less than or equal to the indoor environment humidity threshold value.

The target gas concentration of the indoor environment where the air conditioner is located is less than or equal to the target gas concentration threshold.

The indoor environment in which the air conditioner is located does not have the harmful gas.

If the indoor environment parameter of the air conditioner meets at least one of the following conditions, determining that the indoor environment parameter of the air conditioner does not meet the preset indoor environment parameter condition:

the indoor ambient temperature of the air conditioner is greater than the second indoor ambient temperature threshold.

The indoor ambient temperature of the air conditioner is less than the first indoor ambient temperature threshold.

The indoor ambient humidity of the air conditioner is greater than the indoor ambient humidity threshold.

The target gas concentration of the indoor environment where the air conditioner is located is greater than the target gas concentration threshold.

The indoor environment in which the air conditioner is located has harmful gases.

The voice wake-up instruction processing device configured in the terminal provided by the embodiment of the invention can execute the voice wake-up instruction processing method applied to the terminal provided by any embodiment of the invention, and has the corresponding functional modules and beneficial effects of the execution method.

EXAMPLE III

Fig. 3 is a schematic structural diagram of a terminal according to a third embodiment of the present invention. The terminal shown in fig. 3 is only an example, and should not bring any limitation to the functions and the scope of use of the embodiments of the present invention. As shown in fig. 3, the terminal provided by the embodiment of the present invention includes a processor 21, a memory 22, an input device 23, and an output device 24; the number of the processors 21 in the terminal may be one or more, and one processor 21 is taken as an example in fig. 3; a processor 21, a memory 22, an input device 23, an output device 24 and a voice recognition module in the terminal, wherein the voice recognition module may comprise a first voice wake-up engine 25 and a second voice wake-up engine 26, which may be connected by a bus or other means, for example, in fig. 3.

The memory 22 is used as a computer readable storage medium, and can be used to store software programs, computer executable programs, and modules, such as program instructions/modules corresponding to the voice wake-up instruction processing device of the terminal in the embodiment of the present invention (for example, the integrated state obtaining module 210, the first voice wake-up engine calling module 220, and the first voice wake-up engine calling module 230 in the voice wake-up instruction processing device are used). The processor 21 executes various functional applications and data processing by executing software programs, instructions and modules stored in the memory 22, for example, implementing a voice wake-up instruction processing method applied to a terminal according to an embodiment of the present invention.

The memory 22 may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function; the storage data area may store data created according to the use of the terminal, and the like. Further, the memory 22 may include high speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other non-volatile solid state storage device. In some examples, the memory 22 may further include memory located remotely from the processor 21, which may be connected to the terminal over a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.

The input device 23 may be used to receive numeric or character information input by a user to generate key signal inputs related to user settings and function control of the terminal. The output device 24 may include a display screen or the like. A first voice wake-up engine 25 for responding to the voice wake-up command when the processor 21 determines that the integrated state of the terminal belongs to the first state. A second voice wake-up engine 26 for responding to the voice wake-up instruction when the processor 21 determines that the integrated state of the terminal belongs to the second state.

Of course, those skilled in the art can understand that the processor can also implement the technical solution of the method for processing the voice wake-up instruction applied to the terminal provided by any embodiment of the present invention. The hardware structure and functions of the terminal can be explained with reference to the contents of the embodiments.

Example four

The fourth embodiment of the present invention further provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements a voice wake-up instruction processing method applied to a terminal, where the method includes:

and when the terminal is in a non-awakening state and receives the voice awakening instruction, acquiring the comprehensive state of the terminal.

And if the comprehensive state is the first state, calling the first voice wake-up engine to respond to the voice wake-up instruction.

And if the comprehensive state is the second state, calling a second voice wake-up engine to respond to the voice wake-up instruction.

Computer storage media for embodiments of the invention may employ any combination of one or more computer-readable media. Specific examples (a non-exhaustive list) of the computer readable storage medium would include the following: an electrical connection having one or more wires, a portable Computer diskette, a hard disk, a Random Access Memory (RAM), a Read-Only Memory (ROM), an Erasable Programmable Read-Only Memory (EPROM), a flash Memory, an optical fiber, a portable compact Disc Read-Only Memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing. In the context of this document, a computer readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device.

A computer readable signal medium may include a propagated data signal with computer readable program code embodied therein, for example, in baseband or as part of a carrier wave. Such a propagated data signal may take many forms, including, but not limited to, electro-magnetic, optical, or any suitable combination thereof. A computer readable signal medium may also be any computer readable medium that is not a computer readable storage medium and that can communicate, propagate, or transport a program for use by or in connection with an instruction execution system, apparatus, or device.

Program code embodied on a computer readable medium may be transmitted using any appropriate medium, including but not limited to wireless, wireline, optical fiber cable, radio frequency, etc., or any suitable combination of the foregoing.

Computer program code for carrying out operations for aspects of the present invention may be written in any combination of one or more programming languages, including an object oriented programming language such as Java, Smalltalk, C + + or the like and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may be executed on the terminal.

Of course, the computer-readable storage medium provided in the embodiments of the present invention has computer-executable instructions that are not limited to the method operations described above, and may also perform a method for processing a voice wake-up instruction applied to a terminal provided in any embodiment of the present invention. The description of the storage medium is explained with reference to the embodiments.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A voice wake-up instruction processing method is characterized by comprising the following steps:

2. The method according to claim 1, wherein the obtaining the comprehensive state of the terminal when the voice wake-up command is received while the terminal is in the non-wake-up state comprises:

3. The method of claim 2, wherein the determining the integrated status of the terminal according to the integrated status flag comprises:

4. The method of claim 3, wherein invoking a first voice wake engine in response to the voice wake instruction if the integrated state is the first state comprises:

5. The method of claim 3, wherein invoking a second voice wake engine in response to the voice wake instruction if the integrated state is the second state comprises:

6. The method according to any one of claims 2 to 5, wherein before the receiving the voice wake-up command when the terminal is in the non-wake-up state and acquiring the integrated state identifier of the terminal, the method further comprises:

acquiring a comprehensive mode of a terminal;

7. The method according to claim 6, wherein before the receiving the voice wake-up command when the terminal is in the non-wake-up state and acquiring the integrated state identifier of the terminal, the method further comprises:

acquiring a mobile parameter of a user;

8. The method of claim 7, wherein the obtaining the movement parameters of the user comprises:

9. The method of claim 6, wherein the terminal is an air conditioner, and the indoor environment parameter of the air conditioner comprises at least one of: the air conditioner comprises an indoor environment temperature of the air conditioner, an indoor environment humidity of the air conditioner, a target gas concentration of an indoor environment where the air conditioner is located and harmful gases of the indoor environment where the air conditioner is located;

10. A voice wake-up instruction processing apparatus, comprising:

11. A terminal, comprising:

one or more processors;

a memory for storing one or more programs;

when executed by the one or more processors, cause the one or more processors to implement the method of any one of claims 1-9;

12. A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the method according to any one of claims 1 to 9.