WO2023010859A1 - 用于空调器控制的方法及装置、空调器 - Google Patents
用于空调器控制的方法及装置、空调器 Download PDFInfo
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- WO2023010859A1 WO2023010859A1 PCT/CN2022/082389 CN2022082389W WO2023010859A1 WO 2023010859 A1 WO2023010859 A1 WO 2023010859A1 CN 2022082389 W CN2022082389 W CN 2022082389W WO 2023010859 A1 WO2023010859 A1 WO 2023010859A1
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- temperature
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- air conditioner
- sleep
- heating mode
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- 238000000034 method Methods 0.000 title claims abstract description 51
- 230000007958 sleep Effects 0.000 claims abstract description 73
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
- F24F11/63—Electronic processing
- F24F11/65—Electronic processing for selecting an operating mode
- F24F11/66—Sleep mode
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
- F24F11/80—Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
- F24F2120/10—Occupancy
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
- Y02B30/70—Efficient control or regulation technologies, e.g. for control of refrigerant flow, motor or heating
Definitions
- the present application relates to the technical field of smart home appliances, for example, to a method and device for controlling an air conditioner, and an air conditioner.
- the sleep mode of the air conditioner is suitable for the working mode of the air conditioner during the sleep process of the user. Enabling the sleep mode can solve the inconvenience of adjusting the parameters of the air conditioner for the user during sleep.
- the user has different sleep states after falling asleep.
- the existing air conditioner The sleep mode cannot satisfy the automatic adjustment of corresponding parameters in different sleep states, so that the user can have a comfortable sleep environment.
- the existing technology can correct the target temperature of the air conditioner according to the indoor ambient temperature and the user's sleep state so that the user can have a good sleep environment, it is not comprehensive enough to adjust the air conditioner only according to the temperature and sleep state in practical applications.
- Embodiments of the present disclosure provide a method and device for controlling an air conditioner, and an air conditioner, so as to improve a user's sleep quality and prevent the user from catching a cold.
- the method includes:
- the target temperature TN is determined.
- the target temperature T N is corrected according to the temperature compensation value.
- the device includes a processor and a memory storing program instructions, and the processor is configured to execute the above-mentioned method for air conditioner control when executing the program instructions.
- the air conditioner includes the above-mentioned device for controlling an air conditioner.
- the temperature compensation value is determined to correct the target temperature of the air conditioner, so as to prevent the user from kicking the quilt during sleep and causing a cold.
- FIG. 1 is a schematic diagram of a method for controlling an air conditioner provided by an embodiment of the present disclosure
- Fig. 2 is a schematic diagram of a method for air conditioner control provided by an embodiment of the present disclosure
- Fig. 3 is a schematic diagram of a method for controlling an air conditioner provided by an embodiment of the present disclosure
- Fig. 4 is a schematic diagram of a method for air conditioner control provided by an embodiment of the present disclosure
- Fig. 5 is a schematic diagram of a method for air conditioner control provided by an embodiment of the present disclosure
- Fig. 6 is a schematic diagram of an apparatus for controlling an air conditioner provided by an embodiment of the present disclosure.
- A/B means: A or B.
- a and/or B means: A or B, or, A and B, these three relationships.
- correspondence may refer to an association relationship or a binding relationship, and the correspondence between A and B means that there is an association relationship or a binding relationship between A and B.
- an embodiment of the present disclosure provides a method for controlling an air conditioner, including:
- the air conditioner determines the target temperature T N .
- the air conditioner determines a temperature compensation value according to the sleep state of the user and the degree of coverage of the user.
- the air conditioner corrects the target temperature T N according to the temperature compensation value.
- the air conditioner can determine the target temperature TN when the user falls asleep. Since the user often kicks the quilt after falling asleep, if the air conditioner still operates at the previous target temperature T N , the user will feel cold. Therefore, according to the user's sleep state and the degree of coverage of the user, determine the temperature compensation value to correct the target temperature T N of the air conditioner, so that the corrected target temperature T N matches the user's current sleep state and the degree of coverage of the quilt to avoid The user feels cold because of kicking the quilt during sleep, and even causes a cold, which improves the intelligence of the air conditioner, creates a good sleeping environment for the user, and improves the user experience.
- the air conditioner detecting whether the user falls asleep includes: the air conditioner detecting the user falling asleep, and the air conditioner judges that the user falls asleep when the user is detected falling asleep.
- the sleep state includes falling asleep, light sleep, deep sleep and deep sleep.
- the hypnotic stage is when you start from drowsy, gradually fall asleep, and no longer stay awake. At this time, breathing slows down, muscle tension decreases, and the body is slightly relaxed. This is the state of first sleep, and sleepers are more likely to be awakened by external sounds or touches.
- the stage of light sleep means that the sleeper is not easy to be awakened. At this time, the muscles are further relaxed, and the EEG shows fusiform sleep waves.
- the stage of deep sleep means that the muscle tension of the sleeper disappears at this time, the muscles are fully relaxed, the sensory function is further reduced, and it is more difficult to be awakened.
- the stage of deep sleep means that the sleeper is less likely to be woken up at this time and the brain wave changes greatly.
- the frequency is only 1 to 2 weeks per second, but the amplitude increases greatly, showing a slowly changing curve.
- the air conditioner can detect the user's sleep state by monitoring various physiological parameters of the user through mobile phones, wearable devices or non-wearable devices.
- mobile phone monitoring can use the accelerometer, gyroscope, and microphone that come with the mobile phone to monitor sleep movements, thereby analyzing sleep quality: deep sleep, light sleep, wakefulness, sleep duration, etc.
- Wearable device monitoring through its own acceleration sensor, whether it is a bracelet or a watch, can more accurately perceive the user's motion and biological data through the built-in sensor, so as to analyze the sleep stage.
- Common non-wearable devices include smart mattresses, smart pillows, smart bed bags, smart buckles, etc., which generally have built-in high-sensitivity sensors, which can record the user's sleep quality, heart rate, breathing and snoring conditions to analyze the user's sleep quality. sleep state.
- the air conditioner can start the sleep mode in time, and create a good sleep environment for the user in time, improving the quality of life. user experience.
- the air conditioner determining the target temperature TN includes: the air conditioner determining a reference temperature Tr; and the air conditioner determining the target temperature TN according to the temperature range where the reference temperature Tr is located.
- the air conditioner first determines the reference temperature Tr, and then determines the target temperature TN according to the temperature range in which the reference temperature Tr is located.
- the target temperature TN is determined, which can improve the accuracy of the target temperature TN , make the user more comfortable, and improve the user experience.
- the air conditioner determining the reference temperature Tr includes: in the case of receiving the temperature adjustment instruction, the air conditioner determines the latest temperature set by the user as the user set temperature Ts; in the case of not receiving the temperature adjustment instruction, The air conditioner determines the temperature last set by the user as the user set temperature Ts; the air conditioner determines the reference temperature Tr according to the ambient temperature T and the user set temperature Ts.
- the air conditioner determines the reference temperature Tr, it needs to determine the user's set temperature Ts, so as to meet the user's demand for indoor temperature.
- the user's set temperature Ts can be determined by receiving a temperature adjustment instruction, or the user's set temperature Ts can be automatically determined when no temperature adjustment instruction is received.
- the air conditioner determines the latest temperature set by the user as the user's set temperature Ts, so as to meet the user's demand for temperature to the greatest extent.
- the air conditioner When the air conditioner does not receive the user's temperature adjustment command, at this time, the air conditioner defaults to the user's last set temperature as the user's set temperature Ts to match the user's personal habits and improve the intelligence of the air conditioner. sex. On this basis, the air conditioner determines the reference temperature Tr according to the ambient temperature T and the user's set temperature Ts, which not only considers the influence of the indoor ambient temperature, but also considers the user's demand for indoor temperature after falling asleep, which greatly improves the user experience. .
- T1 is the first temperature threshold
- T2 is the second temperature threshold
- n1 is the first preset value
- n2 is the second preset value
- n3 is the third preset value
- n4 is the fourth preset value Value, in heating mode, n1>T1>n2; in non-heating mode, n3 ⁇ T2 ⁇ n4.
- the air conditioner determines the first preset value n1 greater than the first temperature threshold T1 as the reference temperature Tr. Otherwise, when the user does not have a high demand for temperature in the heating mode, the second preset value n2 that is less than the first temperature threshold is determined as the reference temperature Tr, so as to meet the requirements of the user in the heating mode after falling asleep in most cases. temperature needs.
- the air conditioner determines a third preset value n3 smaller than the second temperature threshold as the reference temperature Tr. Otherwise, when the user does not have a high demand for temperature in the non-heating mode, the air conditioner determines the fourth preset value n4 that is greater than the second temperature threshold as the reference temperature Tr, so as to meet the needs of the user after falling asleep in most cases. Demand for temperature in non-heating mode.
- T3 is the first reference temperature
- T4 is the second reference temperature
- the target temperature T N is determined according to the temperature range where the reference temperature Tr is located, which is more in line with the user's requirements for sleep after falling asleep. temperature requirements.
- the air conditioner determines the reference temperature Tr as the target temperature T N .
- the target temperature T N is determined according to the ambient temperature T and the user’s set temperature Ts, taking into account the ambient temperature T and the user’s set temperature Ts, so that the target temperature can better match the user’s sleeping environment.
- the air conditioner determines the reference temperature Tr as the target temperature T N .
- the target temperature T N is determined according to the ambient temperature T and the user’s set temperature Ts, and the ambient temperature T and the user’s set temperature Ts are considered to make the target temperature more matching
- the user's sleeping environment increases the intelligence of the air conditioner and improves the user experience.
- T5 is the third temperature threshold
- T7 is the first set temperature threshold
- n5 is the fifth preset value
- the target temperature TN is determined according to the ambient temperature T and the user-set temperature Ts .
- the ambient temperature T is less than the third temperature threshold T5
- the user-set temperature Ts is less than the first set temperature threshold T7, at this time, since the user’s temperature demand for heating is not high, the first set The fixed temperature threshold T7 is determined as the target temperature TN , which satisfies the user's basic demand for heating after falling asleep.
- the user set temperature Ts is determined as the target temperature T N to meet the heating needs of the user .
- the ambient temperature T is greater than or equal to the third temperature threshold T5
- the user-set temperature Ts is greater than or equal to the first set temperature threshold T7
- the ambient temperature is relatively high at this time, and will be lower than the third threshold of the user-set temperature Ts.
- the fifth preset value n5 is determined as the target temperature T N , which reduces energy consumption on the basis of meeting the user's heating demand.
- the ambient temperature T is greater than or equal to the third temperature threshold T5, and the user-set temperature Ts is lower than the first set temperature threshold T7, the ambient temperature is relatively high at this time, the user’s demand for heating is not high, and the air conditioner consumes energy Low, the user set temperature Ts is determined as the target temperature T N , which meets the user's demand for heating, reduces the energy consumption of the air conditioner, improves the intelligence of the air conditioner, and improves the user experience.
- T6 is the fourth temperature threshold
- T8 is the second set temperature threshold
- n6 is the sixth preset value
- the target temperature TN is determined according to the ambient temperature T and the user-set temperature Ts.
- the second set temperature threshold T8 is determined as the target temperature T N , to meet the user's demand for non-heating.
- the ambient temperature T is greater than the fourth temperature threshold T6, and the user set temperature Ts is less than or equal to the second set temperature threshold T8, the user set temperature Ts is determined as the target temperature T N to meet the user's requirements for non-heating basic needs.
- the sixth preset value n6 is determined as the target temperature T N , which reduces the energy consumption of the air conditioner on the basis of meeting the user's demand for non-heating temperature to a certain extent.
- the ambient temperature T is less than or equal to the fourth temperature threshold T6, and the user set temperature Ts is greater than the second set temperature threshold T8, at this time, the user's demand for non-heating temperature is not high, and the air conditioner consumes less energy. Low, therefore, the user set temperature Ts is determined as the target temperature T N . It meets the user's demand for temperature in non-heating mode, reduces the energy consumption of the air conditioner, improves the intelligence of the air conditioner, and improves the user experience.
- the air conditioner determining the temperature compensation value according to the user's sleep state and the user's covered degree includes: the air conditioner obtains the user's sleep state and the user's covered degree; The first temperature compensation value N 1 corresponding to the state and the second temperature compensation value N 2 corresponding to the degree of coverage.
- the air conditioner determines the first temperature compensation value N 1 corresponding to the sleep state and the second temperature compensation value N 2 corresponding to the degree of coverage of the user according to the preset corresponding relationship, on the basis of ensuring that the target temperature matches the user's sleep state In addition, fully consider the situation of the user kicking the quilt after falling asleep to prevent the user from catching a cold.
- T P is the corrected target temperature
- N 1 is a non-positive number
- N 2 is a non-negative number
- N 1 and N 2 are both non-negative numbers
- the user's sleep degree It is positively correlated with the absolute value of N 1
- the degree of coverage of the user is negatively correlated with N 2
- N 1 0
- T P T N +N 1 +N 2
- the user's The case of kicking the quilt after falling asleep to prevent the user from catching a cold.
- N 1 is a non-positive number
- the user's sleep degree is positively correlated with the absolute value of N 1 , that is, as the sleep deepens, the target temperature of the air conditioner is lowered to reduce energy consumption.
- N 1 is a non-negative number
- the user's sleep degree is positively correlated with the absolute value of N 1 , that is, as the user's sleep deepens, the target temperature increases to reduce energy consumption and increase The temperature prevents the user from catching a cold.
- N 1 0, that is, to ensure the user's sleep quality
- the temperature compensation value is zero.
- N 2 is a non-negative number, and the degree of coverage of the user is negatively correlated with N 2 , that is, the lower the degree of coverage of the user's quilt, the greater the reduction in the target temperature, preventing the user from catching a cold.
- N 2 0.
- an embodiment of the present disclosure provides a method for controlling an air conditioner, including:
- the air conditioner determines the target temperature T N .
- the air conditioner determines a temperature compensation value according to the sleep state of the user and the degree of coverage of the user.
- the air conditioner corrects the target temperature T N according to the temperature compensation value.
- the air conditioner obtains the fan speed.
- the air conditioner determines a wind speed compensation value corresponding to the fan speed and the sleep state according to a preset correspondence relationship.
- the air conditioner calculates the difference between the fan speed and the wind speed compensation value, and determines the difference as the target fan speed
- the air conditioner adjusts the speed of the fan to the target speed of the fan.
- the fan speed is positively correlated with the wind speed compensation value.
- the wind speed compensation value is zero.
- the air conditioner obtains the fan speed, and when the fan speed is greater than the set speed In this case, the air conditioner determines the wind speed compensation value corresponding to the fan speed and the sleep state according to the preset corresponding relationship, and determines the target fan speed through the wind speed compensation value. In this way, the influence of the fan speed on the user's sleep is considered, so that the user's sleeping environment is less noisy, and the air supply of the air conditioner is softer, which improves the user's sleeping experience.
- an embodiment of the present disclosure provides a method for controlling an air conditioner, including:
- the air conditioner determines the target temperature T N .
- the air conditioner determines a temperature compensation value according to the sleep state of the user and the degree of coverage of the user.
- the air conditioner corrects the target temperature T N according to the temperature compensation value.
- the air conditioner obtains the indoor light brightness
- the air conditioner adjusts the target temperature T N to the user-set temperature Ts.
- the air conditioner adjusts the target temperature T N to the user's set temperature Ts to meet the user's normal demand for temperature, improve the intelligence of the air conditioner, and improve user experience.
- an embodiment of the present disclosure provides a method for controlling an air conditioner, including:
- the air conditioner determines the target temperature T N .
- the air conditioner determines a temperature compensation value according to the sleep state of the user and the degree of coverage of the user.
- the air conditioner corrects the target temperature T N according to the temperature compensation value.
- the air conditioner detects user activity
- the air conditioner adjusts the target temperature T N to the user-set temperature Ts.
- the air conditioner uses the method for air conditioner control provided by the embodiments of the present disclosure to detect that the user's activity continues for the set activity time, at this time, the user is no longer in a sleeping state and does not need to sleep again.
- the air conditioner adjusts the target temperature T N to the user's set temperature Ts to meet the user's normal demand for temperature, improve the intelligence of the air conditioner, and improve user experience.
- an embodiment of the present disclosure provides a method for controlling an air conditioner, including:
- the air conditioner determines the target temperature T N .
- the air conditioner determines a temperature compensation value according to the sleep state of the user and the degree of coverage of the user.
- the air conditioner corrects the target temperature T N according to the temperature compensation value.
- the air conditioner adjusts the target temperature T N to the user-set temperature Ts.
- the air conditioner adjusts the target temperature T N to the user's set temperature Ts to meet the user's normal demand for temperature, improve the intelligence of the air conditioner, and improve user experience.
- an embodiment of the present disclosure provides an apparatus for controlling an air conditioner, including a processor (processor) 100 and a memory (memory) 101 .
- the device may also include a communication interface (Communication Interface) 102 and a bus 103.
- Communication interface 102 may be used for information transfer.
- the processor 100 can invoke logic instructions in the memory 101 to execute the method for controlling an air conditioner in the above embodiments.
- the above logic instructions in the memory 101 may be implemented in the form of software functional units and may be stored in a computer-readable storage medium when sold or used as an independent product.
- the memory 101 can be used to store software programs and computer-executable programs, such as program instructions/modules corresponding to the methods in the embodiments of the present disclosure.
- the processor 100 executes the program instructions/modules stored in the memory 101 to execute functional applications and data processing, that is, to implement the method for air conditioner control in the above-mentioned embodiments.
- the memory 101 may include a program storage area and a data storage area, wherein the program storage area may store an operating system and an application program required by at least one function; the data storage area may store data created according to the use of the terminal device, and the like.
- the memory 101 may include a high-speed random access memory, and may also include a non-volatile memory.
- An embodiment of the present disclosure provides an air conditioner, including the above-mentioned device for controlling an air conditioner.
- An embodiment of the present disclosure provides a storage medium storing computer-executable instructions, and the computer-executable instructions are configured to execute the above-mentioned method for controlling an air conditioner.
- the above-mentioned storage medium may be a transient storage medium or a non-transitory storage medium.
- the technical solutions of the embodiments of the present disclosure can be embodied in the form of software products, which are stored in a storage medium and include one or more instructions to make a computer device (which can be a personal computer, a server, or a network equipment, etc.) to perform all or part of the steps of the method described in the embodiments of the present disclosure.
- the aforementioned storage medium can be a non-transitory storage medium, including: U disk, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), magnetic disk or optical disc, etc.
- the term “and/or” as used in this application is meant to include any and all possible combinations of one or more of the associated listed ones.
- the term “comprise” and its variants “comprises” and/or comprising (comprising) etc. refer to stated features, integers, steps, operations, elements, and/or The presence of a component does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components and/or groupings of these.
- an element defined by the statement “comprising a " does not exclude the presence of additional identical elements in the process, method or apparatus comprising said element.
- the disclosed methods and products can be implemented in other ways.
- the device embodiments described above are only illustrative.
- the division of the units may only be a logical function division.
- multiple units or components may be combined Or it can be integrated into another system, or some features can be ignored, or not implemented.
- the mutual coupling or direct coupling or communication connection shown or discussed may be through some interfaces, and the indirect coupling or communication connection of devices or units may be in electrical, mechanical or other forms.
- each functional unit in the embodiments of the present disclosure may be integrated into one processing unit, each unit may exist separately physically, or two or more units may be integrated into one unit.
- each block in a flowchart or block diagram may represent a module, program segment, or part of code that includes one or more Executable instructions.
- the functions noted in the block may occur out of the order noted in the figures.
- two blocks in succession may, in fact, be executed substantially concurrently, or they may sometimes be executed in the reverse order, depending upon the functionality involved.
- the operations or steps corresponding to different blocks may also occur in a different order than that disclosed in the description, and sometimes there is no specific agreement between different operations or steps.
- each block in the block diagrams and/or flowcharts, and combinations of blocks in the block diagrams and/or flowcharts can be implemented by a dedicated hardware-based system that performs the specified function or action, or can be implemented by dedicated hardware implemented in combination with computer instructions.
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Abstract
本申请涉及智能家电技术领域,公开一种用于空调器控制的方法,包括:在用户进入睡眠的情况下,确定目标温度T N;根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值;根据温度补偿值修正目标温度T N。在用户进入睡眠后,根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值以修正空调器的目标温度,以避免用户在睡眠过程中踢被子导致感冒。本申请还公开一种用于空调器控制的装置及空调器。
Description
本申请基于申请号为202110876593.8、申请日为2021年7月31日的中国专利申请提出,并要求该中国专利申请的优先权,该中国专利申请的全部内容在此引入本申请作为参考。
本申请涉及智能家电技术领域,例如涉及一种用于空调器控制的方法及装置、空调器。
目前,随着人们生活水平的提高,智能技术的发展,人们对空调器的智能性也提出了更高的需求。空调器的睡眠模式是适于用户睡眠过程中的空调器工作模式,启用睡眠模式可以为睡眠中用户解决调节空调参数的不便,但是,用户在入睡后有着不同的睡眠状态,现有空调器的睡眠模式无法满足在不同的睡眠状态进行相应的参数的自动调整,使用户拥有舒适的睡眠环境。
现有技术中存在一种空调器在睡眠模式时的控制方案,通过在睡眠模式下,获取室内环境温度与设定的目标温度的温度差值,并匹配用户当前的睡眠状态以对目标温度进行修正,使空调按修正后的目标温度运行,实现了睡眠模式下的智能控温。
在实现本公开实施例的过程中,发现相关技术中至少存在如下问题:
现有技术虽然能够根据室内环境温度和用户的睡眠状态修正空调目标温度以使用户有良好的睡眠环境,但是在实际应用中仅仅根据温度和睡眠状态来调节空调器是不够全面的。
发明内容
为了对披露的实施例的一些方面有基本的理解,下面给出了简单的概括。所述概括不是泛泛评述,也不是要确定关键/重要组成元素或描绘这些实施例的保护范围,而是作为后面的详细说明的序言。
本公开实施例提供了一种用于空调器控制的方法及装置、空调器,以提高用户的睡眠质量,避免用户感冒。
在一些实施例中,所述方法包括:
在用户进入睡眠的情况下,确定目标温度T
N。
根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
根据温度补偿值修正目标温度T
N。
在一些实施例中,所述装置包括处理器和存储有程序指令的存储器,处理器被配置为在执行程序指令时,执行上述的用于空调器控制的方法。
在一些实施例中,所述空调器包括上述的用于空调器控制的装置。
本公开实施例提供的用于空调器控制的方法及装置、空调器可以实现以下技术效果:
在用户进入睡眠后,根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值以修正空调器的目标温度,以避免用户在睡眠过程中踢被子导致感冒。
以上的总体描述和下文中的描述仅是示例性和解释性的,不用于限制本申请。
一个或多个实施例通过与之对应的附图进行示例性说明,这些示例性说明和附图并不构成对实施例的限定,附图中具有相同参考数字标号的元件示为类似的元件,附图不构成比例限制,并且其中:
图1是本公开实施例提供的一个用于空调器控制的方法的示意图;
图2是本公开实施例提供的一个用于空调器控制的方法的示意图;
图3是本公开实施例提供的一个用于空调器控制的方法的示意图;
图4是本公开实施例提供的一个用于空调器控制的方法的示意图;
图5是本公开实施例提供的一个用于空调器控制的方法的示意图;
图6是本公开实施例提供的一个用于空调器控制的装置的示意图。
为了能够更加详尽地了解本公开实施例的特点与技术内容,下面结合附图对本公开实施例的实现进行详细阐述,所附附图仅供参考说明之用,并非用来限定本公开实施例。在以下的技术描述中,为方便解释起见,通过多个细节以提供对所披露实施例的充分理解。 然而,在没有这些细节的情况下,一个或多个实施例仍然可以实施。在其它情况下,为简化附图,熟知的结构和装置可以简化展示。
本公开实施例的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。应该理解这样使用的数据在适当情况下可以互换,以便这里描述的本公开实施例的实施例。此外,术语“包括”和“具有”以及他们的任何变形,意图在于覆盖不排他的包含。
除非另有说明,术语“多个”表示两个或两个以上。
本公开实施例中,字符“/”表示前后对象是一种“或”的关系。例如,A/B表示:A或B。
术语“和/或”是一种描述对象的关联关系,表示可以存在三种关系。例如,A和/或B,表示:A或B,或,A和B这三种关系。
术语“对应”可以指的是一种关联关系或绑定关系,A与B相对应指的是A与B之间是一种关联关系或绑定关系。
结合图1所示,本公开实施例提供一种用于空调器控制的方法,包括:
S01,在用户进入睡眠的情况下,空调器确定目标温度T
N。
S02,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
S03,空调器根据温度补偿值修正目标温度T
N。
采用本公开实施例提供的用于空调器控制的方法,空调器能在用户进入睡眠的情况下,确定目标温度T
N。由于用户在进入睡眠后,经常会发生踢被子等行为,如果空调器仍然按照之前的目标温度T
N运行,会使用户感到寒冷。因此,根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值以修正空调器的目标温度T
N,使修正后的目标温度T
N匹配用户当前的睡眠状态以及被子的覆盖程度,以避免用户在睡眠过程中因为踢被子感到寒冷,甚至导致感冒,提高了空调器的智能性,为用户营造良好的睡眠环境,提升了用户体验。
可选地,空调器检测用户是否进入睡眠包括:空调器检测用户睡眠状态,在检测到用户处于入睡状态下,空调器判断用户进入睡眠。
其中,睡眠状态包括入睡、浅睡、熟睡和深睡。入睡阶段是指,从昏昏欲睡开始,逐渐入睡,不再保持觉醒状态。这时候,呼吸变慢,肌肉张力下降,身体轻度放松,此时属于初睡状态,睡眠者较易被外界声音或触动所唤醒。浅睡阶段是指,睡眠者已不易被唤醒,此时肌肉进一步放松,脑电图显示梭状睡眠波。熟睡阶段是指,这时候睡眠者肌张力消失,肌肉充分松弛,感觉功能进一步降低,更不易被唤醒。深睡阶段是指,此时睡眠者更不易被叫醒且脑波变化很大,频率只有每秒1~2周,但振幅增加较大,呈现变化缓慢的曲线。具体的,空调器检测用户的睡眠状态可以通过手机、可穿戴设备或非可穿戴设备监测用户 的各项生理参数实现。例如,手机监测可利用手机自带的加速度传感器、陀螺仪、麦克风来监测睡觉动作,从而分析睡眠质量:深睡、浅睡、清醒、睡眠时长等。可穿戴设备监测通过自身的加速传感器,无论是手环还是手表,都可以通过内置的传感器更准确的感知用户动作、生物数据,以此分析睡眠阶段。非穿戴设备比较常见的有智能床垫、智能枕头、智能床袋、智能别扣等,一般都会内置的高灵敏度传感器,它们可以记录用户的睡眠质量、心率、呼吸和打鼾情况,以分析用户的睡眠状态。
这样,通过检测用户的睡眠状态(入睡、浅睡、熟睡和深睡),可以准确地判断用户何时进入睡眠状态,使空调能够及时启动睡眠模式,并及时为用户营造良好的睡眠环境,提升了用户体验。
可选地,空调器确定目标温度T
N包括:空调器确定基准温度Tr;空调器根据基准温度Tr所在的温度区间确定目标温度T
N。
这样,空调器先确定基准温度Tr,再根据基准温度Tr所在的温度区间确定目标温度T
N。通过基准温度Tr的设立,在确定基准温度Tr的基础上,确定目标温度T
N,能够提高目标温度T
N的准确性,使用户更加舒适,提升了用户体验。
可选地,空调器确定基准温度Tr包括:在接收到温度调节指令的情况下,空调器将用户最新设定的温度确定为用户设定温度Ts;在未接收到温度调节指令的情况下,空调器将用户最近一次设定的温度确定为用户设定温度Ts;空调器根据环境温度T和用户设定温度Ts确定基准温度Tr。
这样,空调器确定基准温度Tr前,需要确定用户设定温度Ts,以满足用户对室内温度的需求。既可以接收温度调节指令来确定用户设定温度Ts,也可以在未接收到温度调节指令的情况下,自动确定用户设定温度Ts。在接收到用户的温度调节指令的情况下,此时,用户对室内温度有需求,空调器将用户最新设定的温度确定为用户设定温度Ts,最大程度满足用户对温度的需求。在空调器未接收到用户的温度调节指令的情况下,此时,空调器默认将用户最近一次设定的温度确定为用户设定温度Ts,以匹配用户的个人习惯,提升了空调器的智能性。在此基础上,空调器根据环境温度T和用户设定温度Ts确定基准温度Tr,既考虑了室内环境温度的影响,又考虑了用户在入睡后对室内温度的需求,极大地提升了用户体验。
可选地,空调器根据环境温度T和用户设定温度Ts确定基准温度Tr包括:在制热模式下,如果T≥T1且Ts>T1,则空调器确定Tr=n1;否则,空调器确定Tr=n2;在非制热模式下,T≤T2且Ts<T2,则空调器确定Tr=n3;否则,空调器确定Tr=n4。
其中,T1为第一温度阈值,T2为第二温度阈值,T1>T2;n1为第一预设值,n2为第 二预设值、n3为第三预设值,n4为第四预设值,在制热模式下,n1>T1>n2;在非制热模式下,n3<T2<n4。
这样,在制热模式下,如果环境温度T大于或等于第一温度阈T1,并且用户设定温度Ts大于第一温度阈值T1,此时为环境温度较高,用户却对制热模式时的温度仍然有较高需求的情况,为满足用户入睡后对制热模式温度的较高的需求,空调器将大于第一温度阈值T1的第一预设值n1确定为基准温度Tr。否则,用户对制热模式时温度需求不高的情况下,将小于第一温度阈值的第二预设值n2确定为基准温度Tr,以满足绝大多数情况下用户入睡后对制热模式时温度的需求。在非制热模式下,如果环境温度T小于或等于第二温度阈值T2,并且用户设定温度Ts小于第二温度阈值T2,此时为环境温度较低,用户却对非制热有较高需求的情况。为了满足用户对非制热模式时对温度的需求,空调器将小于第二温度阈值的第三预设值n3确定为基准温度Tr。否则,用户对非制热模式时温度的需求不高的情况下,空调器将大于第二温度阈值的第四预设值确定n4确定为基准温度Tr,以满足绝大多数情况下用户入睡后对非制热模式时温度的需求。
可选地,空调器根据基准温度Tr所在的温度区间确定目标温度T
N包括:在制热模式下,如果Tr>T3,则空调器确定T
N=Tr;否则,空调器根据环境温度T和用户设定温度Ts确定目标温度T
N;在非制热模式下,如果Tr<T4;则空调器T
N=Tr;否则,空调器根据环境温度T和用户设定温度Ts确定目标温度T
N。
其中,T3为第一基准温度,T4为第二基准温度,T3>T4。
这样,由于基准温度很大程度上体现了用户在制热模式或者非制热模式时对温度的需求,因此,根据基准温度Tr所在的温度区间确定目标温度T
N,更加符合用户对入睡后的温度的需求。在制热模式下,如果基准温度大于第一基准温度,此时,用户对制热温度有较高的需求,为了满足用户对制热的需求,空调器将基准温度Tr确定为目标温度T
N。否则,在用户对制热需求不高的情况下,根据环境温度T和用户设定温度Ts确定目标温度T
N,考虑了环境温度T和用户设定温度Ts,以使目标温度更加匹配用户的睡眠环境。在非制热模式下,如果基准温度小于第二基准温度,此时,用户对非制热有较高的需求,为了满足用户对非制热的需求,空调器将基准温度Tr确定为目标温度T
N。否则,在用户对非制热温度需求不高的情况下,根据环境温度T和用户设定温度Ts确定目标温度T
N,考虑了环境温度T和用户设定温度Ts,以使目标温度更加匹配用户的睡眠环境,增加了空调器的智能性,提升了用户体验。
可选地,在制热模式下,空调器根据环境温度T和用户设定温度Ts确定目标温度T
N包括:在T<T5且Ts<T7的情况下,则空调器确定T
N=T7;在T<T5且Ts≥T7的情况下, 则空调器确定T
N=Ts;在T≥T5且Ts≥T7的情况下,则空调器确定T
N=n5;在T≥T5且Ts<T7的情况下,则空调器确定T
N=Ts。
其中,T5为第三温度阈值,T7为第一设定温度阈值,n5为第五预设值,T5<n5<T7。
这样,在用户对制热模式下的温度需求不高的情况下,根据环境温度T和用户设定温度Ts确定目标温度T
N。在制热模式下,如果环境温度T小于第三温度阈值T5,并且用户设定温度Ts小于第一设定温度阈值T7,此时,由于用户对制热的温度需求不高,将第一设定温度阈值T7确定为目标温度T
N,满足了用户入睡后对制热基本的需求。在环境温度T小于第三温度阈值T5,并且用户设定温度Ts大于或等于第一设定温度阈值T7的情况下,将用户设定温度Ts确定为目标温度T
N,满足用户制热的需求。在环境温度T大于或等于第三温度阈值T5,并且用户设定温度Ts大于或等于第一设定温度阈值T7的情况下,此时环境温度较高,将低于用户设定温度Ts的第五预设值n5确定为目标温度T
N,在满足用户制热需求的基础上,降低了能耗。在环境温度T大于或等于第三温度阈值T5,并且用户设定温度Ts小于第一设定温度阈值T7的情况下,此时环境温度较高,用户对制热需求不高,空调器耗能低,将用户设定温度Ts确定为目标温度T
N,满足了用户对制热的需求,降低空调的能耗,提高了空调器的智能性,提升了用户体验。
可选地,在非制热模式下,空调器根据环境温度T和用户设定温度Ts确定目标温度T
N包括:在T>T6且Ts>T8的情况下,则空调器确定T
N=T8;在T>T6且Ts≤T8的情况下,则空调器确定T
N=Ts;在T≤T6且Ts≤T8的情况下,则空调器确定T
N=n6;在T≤T6且Ts>T8的情况下,则空调器确定T
N=Ts。
其中,T6为第四温度阈值,T8为第二设定温度阈值,n6为第六预设值,T8<n6<T6。
这样,在用户对非制热模式下的温度需求不高的情况下,根据环境温度T和用户设定温度Ts确定目标温度T
N。在非制热模式下,在环境温度T大于第四温度阈值T6,并且,用户设定温度Ts大于第二设定温度阈值T8的情况下,将第二设定温度阈值T8确定为目标温度T
N,满足了用户对非制热的需求。在环境温度T大于第四温度阈值T6,并且用户设定温度Ts小于或等于第二设定温度阈值T8的情况下,将用户设定温度Ts确定为目标温度T
N,满足用户对非制热的基本需求。在环境温度T小于或等于第四温度阈值T6,并且用户设定温度Ts小于或等于第二设定温度阈值T8的情况下,此时,环境温度较低,但是用户对非制热需求相对较高,为了减少能耗,将第六预设值确定n6确定为目标温度T
N,一定程度满足用户对非制热温度需求的基础上,减少了空调器的能耗。在环境温度T小于或等于第四温度阈值T6,并且用户设定温度Ts大于第二设定温度阈值T8的情况下,此时,用户对非制热温度的需求不高,空调器能耗较低,因此,将用户设定温度Ts确定为目标温 度T
N。满足了用户对非制热模式下温度的需求,并且降低空调的能耗,提高了空调器的智能性,提升了用户体验。
可选地,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值包括:空调器获取用户的睡眠状态和用户的被覆盖程度;空调器根据预设的对应关系,确定与睡眠状态对应的第一温度补偿值N
1和与被覆盖程度对应的第二温度补偿值N
2。
这样,空调器根据预设的对应关系,确定与睡眠状态对应的第一温度补偿值N
1和与用户被覆盖程度对应的第二温度补偿值N
2,在保证目标温度匹配用户睡眠状态的基础上,充分考虑了用户在入睡后踢被子的情况,避免用户感冒。
可选地,空调器根据温度补偿值修正目标温度T
N包括:空调器计算T
P=T
N+N
1+N
2。
其中,T
P为修正后的目标温度;在制热模式下,N
1为非正数、N
2为非负数、在非制热模式下N
1、N
2均为非负数;用户的睡眠程度与N
1的绝对值呈正相关;用户的被覆盖程度与N
2呈负相关;在用户进入深睡阶段持续设定时间,N
1=0;在被覆盖程度大于设定百分比的情况下,N
2=0。
这样,空调器计算T
P=T
N+N
1+N
2,通过第一温度补偿值和第二温度补偿值修正目标温度,在保证目标温度匹配用户睡眠状态的基础上,充分考虑了用户在入睡后踢被子的情况,避免用户感冒。在制热模式下,N
1为非正数,用户的睡眠程度与N
1的绝对值呈正相关,即随着睡眠的深入,空调器的目标温度降低幅度越大,以降低能耗。在非制热模式下,N
1为非负数,用户的睡眠程度与N
1的绝对值呈正相关,即随着用户的睡眠的深入,目标温度增加幅度变大,以减少能耗,同时升高温度避免用户感冒。在用户进入深睡阶段持续设定时间,N
1=0,即为保证用户睡眠质量,温度补偿值为零。N
2为非负数,用户的被覆盖程度与N
2呈负相关,即用户的被子的覆盖程度越低,目标温度降低幅度越大,避免用户感冒。在用户的被覆盖程度大于设定百分比的情况下,此时,用户的被覆盖程度处于正常范围,因此,N
2=0。通过以上方案,考虑了用户入睡后的踢被子的状况,降低了用户入睡后感冒的概率,提升了用户的睡眠体验。
结合图2所示,本公开实施例提供一种用于空调器控制的方法,包括:
S01,在用户进入睡眠的情况下,空调器确定目标温度T
N。
S02,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
S03,空调器根据温度补偿值修正目标温度T
N。
S21,空调器获取风机转速。
S22,在风机转速大于设定转速的情况下,空调器根据预设的对应关系,确定与风机转速和睡眠状态对应的风速补偿值。
S23,空调器计算风机转速与风速补偿值的差值,将差值确定为目标风机转速;
S24,空调器调节风机的转速至目标风机转速。
其中,风机转速与风速补偿值呈正相关。在风机转速小于或等于设定风速的情况下,风速补偿值为零。
采用本公开实施例提供的用于空调器控制的方法,在用户入睡后,风机转速也会影响室内的噪音以及送风口风速快慢,因此,空调器获取风机转速,在风机转速大于设定转速的情况下,空调器根据预设的对应关系,确定与风机转速和睡眠状态对应的风速补偿值,并通过风速补偿值确定目标风机转速。这样,考虑了风机转速对用户睡眠的影响,使用户的睡眠环境噪音小,空调器送风更加轻柔,提升了用户睡眠体验。
结合图3所示,本公开实施例提供一种用于空调器控制的方法,包括:
S01,在用户进入睡眠的情况下,空调器确定目标温度T
N。
S02,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
S03,空调器根据温度补偿值修正目标温度T
N。
S31,空调器获取室内的光线亮度;
S32,在光线亮度达到设定亮度的情况下,空调器调节目标温度T
N至用户设定温度Ts。
采用本公开实施例提供的用于空调器控制的方法,在室内亮度达到设定亮度的情况下,此时,用户不需要再进行睡眠。空调器调节目标温度T
N至用户设定温度Ts,满足用户对温度的正常需求,提高了空调器的智能性,提升了用户体验。
结合图4所示,本公开实施例提供一种用于空调器控制的方法,包括:
S01,在用户进入睡眠的情况下,空调器确定目标温度T
N。
S02,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
S03,空调器根据温度补偿值修正目标温度T
N。
S41,空调器检测用户活动情况;
S42,在用户起床活动持续设定活动时间后,空调器调节目标温度T
N至用户设定温度Ts。
采用本公开实施例提供的用于空调器控制的方法,在空调器检测到用户活动情况持续设定活动时间的情况下,此时,用户已不在睡眠的状态中,不需要再进行睡眠。空调器调节目标温度T
N至用户设定温度Ts,满足用户对温度的正常需求,提高了空调器的智能性,提升了用户体验。
结合图5所示,本公开实施例提供一种用于空调器控制的方法,包括:
S01,在用户进入睡眠的情况下,空调器确定目标温度T
N。
S02,空调器根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值。
S03,空调器根据温度补偿值修正目标温度T
N。
S51,在用户取消睡眠模式的情况下,空调器调节目标温度T
N至用户设定温度Ts。
采用本公开实施例提供的用于空调器控制的方法,在用户取消睡眠模式的情况下,此时,用户不需要再进行睡眠。空调器调节目标温度T
N至用户设定温度Ts,满足用户对温度的正常需求,提高了空调器的智能性,提升了用户体验。
结合图6所示,本公开实施例提供一种用于空调器控制的装置,包括处理器(processor)100和存储器(memory)101。可选地,该装置还可以包括通信接口(Communication Interface)102和总线103。其中,处理器100、通信接口102、存储器101可以通过总线103完成相互间的通信。通信接口102可以用于信息传输。处理器100可以调用存储器101中的逻辑指令,以执行上述实施例的用于空调器控制的方法。
此外,上述的存储器101中的逻辑指令可以通过软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。
存储器101作为一种计算机可读存储介质,可用于存储软件程序、计算机可执行程序,如本公开实施例中的方法对应的程序指令/模块。处理器100通过运行存储在存储器101中的程序指令/模块,从而执行功能应用以及数据处理,即实现上述实施例中用于空调器控制的方法。
存储器101可包括存储程序区和存储数据区,其中,存储程序区可存储操作系统、至少一个功能所需的应用程序;存储数据区可存储根据终端设备的使用所创建的数据等。此外,存储器101可以包括高速随机存取存储器,还可以包括非易失性存储器。
本公开实施例提供了一种空调器,包含上述的用于空调器控制的装置。
本公开实施例提供了一种存储介质,存储有计算机可执行指令,所述计算机可执行指令设置为执行上述用于空调器控制的方法。
上述的存储介质可以是暂态存储介质,也可以是非暂态存储介质。
本公开实施例的技术方案可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括一个或多个指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本公开实施例所述方法的全部或部分步骤。而前述的存储介质可以是非暂态存储介质,包括:U盘、移动硬盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等多种可以存储程序代码的介质,也可以是暂态存储介质。
以上描述和附图充分地示出了本公开的实施例,以使本领域的技术人员能够实践它们。 其他实施例可以包括结构的、逻辑的、电气的、过程的以及其他的改变。实施例仅代表可能的变化。除非明确要求,否则单独的部件和功能是可选的,并且操作的顺序可以变化。一些实施例的部分和特征可以被包括在或替换其他实施例的部分和特征。而且,本申请中使用的用词仅用于描述实施例并且不用于限制权利要求。如在实施例以及权利要求的描述中使用的,除非上下文清楚地表明,否则单数形式的“一个”(a)、“一个”(an)和“所述”(the)旨在同样包括复数形式。类似地,如在本申请中所使用的术语“和/或”是指包含一个或一个以上相关联的列出的任何以及所有可能的组合。另外,当用于本申请中时,术语“包括”(comprise)及其变型“包括”(comprises)和/或包括(comprising)等指陈述的特征、整体、步骤、操作、元素,和/或组件的存在,但不排除一个或一个以上其它特征、整体、步骤、操作、元素、组件和/或这些的分组的存在或添加。在没有更多限制的情况下,由语句“包括一个…”限定的要素,并不排除在包括所述要素的过程、方法或者设备中还存在另外的相同要素。本文中,每个实施例重点说明的可以是与其他实施例的不同之处,各个实施例之间相同相似部分可以互相参见。对于实施例公开的方法、产品等而言,如果其与实施例公开的方法部分相对应,那么相关之处可以参见方法部分的描述。
本领域技术人员可以意识到,结合本文中所公开的实施例描述的各示例的单元及算法步骤,能够以电子硬件、或者计算机软件和电子硬件的结合来实现。这些功能究竟以硬件还是软件方式来执行,可以取决于技术方案的特定应用和设计约束条件。所述技术人员可以对每个特定的应用来使用不同方法以实现所描述的功能,但是这种实现不应认为超出本公开实施例的范围。所述技术人员可以清楚地了解到,为描述的方便和简洁,上述描述的系统、装置和单元的具体工作过程,可以参考前述方法实施例中的对应过程,在此不再赘述。
本文所披露的实施例中,所揭露的方法、产品(包括但不限于装置、设备等),可以通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如,所述单元的划分,可以仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另外,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例。另外,在本公开实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成 在一个单元中。
附图中的流程图和框图显示了根据本公开实施例的系统、方法和计算机程序产品的可能实现的体系架构、功能和操作。在这点上,流程图或框图中的每个方框可以代表一个模块、程序段或代码的一部分,所述模块、程序段或代码的一部分包含一个或多个用于实现规定的逻辑功能的可执行指令。在有些作为替换的实现中,方框中所标注的功能也可以以不同于附图中所标注的顺序发生。例如,两个连续的方框实际上可以基本并行地执行,它们有时也可以按相反的顺序执行,这可以依所涉及的功能而定。在附图中的流程图和框图所对应的描述中,不同的方框所对应的操作或步骤也可以以不同于描述中所披露的顺序发生,有时不同的操作或步骤之间不存在特定的顺序。例如,两个连续的操作或步骤实际上可以基本并行地执行,它们有时也可以按相反的顺序执行,这可以依所涉及的功能而定。框图和/或流程图中的每个方框、以及框图和/或流程图中的方框的组合,可以用执行规定的功能或动作的专用的基于硬件的系统来实现,或者可以用专用硬件与计算机指令的组合来实现。
Claims (10)
- 一种用于空调器控制的方法,其特征在于,包括:在用户进入睡眠的情况下,确定目标温度T N;根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值;根据所述温度补偿值修正所述目标温度T N。
- 根据权利要求1所述的方法,其特征在于,所述确定目标温度T N,包括:确定基准温度Tr;根据所述基准温度Tr所在的温度区间确定所述目标温度T N。
- 根据权利要求2所述的方法,其特征在于,所述确定基准温度Tr,包括:在接收到温度调节指令的情况下,将用户最新设定的温度确定为用户设定温度Ts;在未接收到温度调节指令的情况下,将用户最近一次设定的温度确定为所述用户设定温度Ts;根据环境温度T和所述用户设定温度Ts确定所述基准温度Tr。
- 根据权利要求3所述的方法,其特征在于,所述根据环境温度T和所述用户设定温度Ts确定所述基准温度Tr,包括:在制热模式下,如果T≥T1且Ts>T1,则Tr=n1;否则,Tr=n2;在非制热模式下,T≤T2且Ts<T2,则Tr=n3;否则,Tr=n4;其中,T1为第一温度阈值,T2为第二温度阈值,T1>T2;n1为第一预设值,n2为第二预设值、n3为第三预设值,n4为第四预设值,在制热模式下,n1>T1>n2;在非制热模式下,n3<T2<n4。
- 根据权利要求3所述的方法,其特征在于,所述根据所述基准温度Tr所在的温度区间确定所述目标温度T N,包括:在制热模式下,如果Tr>T3,则T N=Tr;否则,根据所述环境温度T和所述用户设定温度Ts确定所述目标温度T N;在非制热模式下,如果Tr<T4;则T N=Tr;否则,根据所述环境温度T和所述用户设定温度Ts确定所述目标温度T N;其中,T3为第一基准温度,T4为第二基准温度,T3>T4。
- 根据权利要求5所述的方法,其特征在于,在制热模式下,根据所述环境温度T和所述用户设定温度Ts确定所述目标温度T N,包括:在T<T5且Ts<T7的情况下,则T N=T7;在T<T5且Ts≥T7的情况下,则T N=Ts;在T≥T5且Ts≥T7的情况下,则T N=n5;在T≥T5且Ts<T7的情况下,则T N=Ts;其中,T5为第三温度阈值,T7为第一设定温度阈值,n5为第五预设值,T5<n5<T7。
- 根据权利要求5所述的方法,其特征在于,在非制热模式下,根据所述环境温度T和所述用户设定温度Ts确定所述目标温度T N,包括:在T>T6且Ts>T8的情况下,则T N=T8;在T>T6且Ts≤T8的情况下,则T N=Ts;在T≤T6且Ts≤T8的情况下,则T N=n6;在T≤T6且Ts>T8的情况下,则T N=Ts;其中,T6为第四温度阈值,T8为第二设定温度阈值,n6为第六预设值,T8<n6<T6。
- 根据权利要求1至7任一项所述的方法,其特征在于,所述根据用户的睡眠状态和用户的被覆盖程度,确定温度补偿值,包括:获取用户的睡眠状态和用户的被覆盖程度;根据预设的对应关系,确定与所述睡眠状态对应的第一温度补偿值N 1和与所述被覆盖程度对应的第二温度补偿值N 2。
- 一种用于空调器控制的装置,包括处理器和存储有程序指令的存储器,其特征在于,所述处理器被配置为在执行所述程序指令时,执行如权利要求1至8任一项所述的用于空调器控制的方法。
- 一种空调器,其特征在于,包括如权利要求9所述的用于空调器控制的装置。
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