CN115349737A

CN115349737A - Partitioned hardness and softness adjusting method of intelligent mattress and related product

Info

Publication number: CN115349737A
Application number: CN202210959844.3A
Authority: CN
Inventors: 王炳坤
Original assignee: De Rucci Healthy Sleep Co Ltd
Current assignee: De Rucci Healthy Sleep Co Ltd
Priority date: 2022-08-11
Filing date: 2022-08-11
Publication date: 2022-11-18
Anticipated expiration: 2042-08-11
Also published as: CN115349737B

Abstract

The embodiment of the application relates to the technical field of intelligent home furnishing, and discloses a partition hardness and softness adjusting method of an intelligent mattress and a related product, wherein the intelligent mattress is divided into a left partition and a right partition, the hardness of the left partition is different from that of the right partition, and the method comprises the following steps: the smart mattress detects that a first user on the first zone gets up and leaves the first zone; wherein the first partition is the left partition or the right partition; the intelligent mattress identifies whether a second user exists on the second partition; if so, adjusting the hardness of the first partition to be consistent with that of the second partition; the second partition is another partition other than the first partition among the left partition and the right partition described above. By implementing the embodiment of the application, the user can be prevented from generating discomfort caused by inconsistent hardness and softness when turning over from one partition of the left partition and the right partition of the intelligent mattress to the other partition.

Description

Partitioned hardness and softness adjusting method of intelligent mattress and related product

Technical Field

The application relates to the technical field of intelligent home, in particular to a partitioned hardness and softness adjusting method of an intelligent mattress and a related product.

Background

At present, some intelligent mattresses in the market are divided into a left partition and a right partition, and the left partition can be inflated according to an input left partition hardness adjusting instruction to adjust the hardness of the left partition; and according to the input right partition hardness and softness adjusting instruction, inflating the right partition to adjust the hardness and softness of the right partition, so that the hardness and softness of the left partition and the right partition can be independently adjusted.

In practice, it is found that when a user in one of the left and right subareas gets up and leaves the subarea, if another user in the other subarea turns over to the other subarea, the other user often feels discomfort due to the change of hardness and softness.

Disclosure of Invention

The embodiment of the application discloses a method for adjusting the hardness of a partition of an intelligent mattress and a related product, which can avoid the discomfort caused by inconsistent hardness when a user turns over from one partition of a left partition and a right partition of the intelligent mattress to the other partition.

The embodiment of the application discloses in a first aspect a method for adjusting hardness of a partition of an intelligent mattress, wherein the intelligent mattress is divided into a left partition and a right partition, and the hardness of the left partition is different from that of the right partition, and the method comprises the following steps:

the smart mattress detects that a first user on a first zone gets up to leave the first zone; wherein the first partition is the left partition or the right partition;

the smart mattress identifies whether a second user is present on a second zone; if so, adjusting the hardness of the first partition to be consistent with that of the second partition; the second partition is another partition of the left partition and the right partition other than the first partition.

As an optional implementation manner, in the first aspect of this embodiment of the present application, after the intelligent mattress adjusts the hardness of the first partition to be consistent with the hardness of the second partition, the method further includes:

the intelligent mattress identifies whether the currently set temperature of the first partition is consistent with the currently set temperature of the second partition;

if the temperature of the first partition is inconsistent with the temperature of the second partition, the intelligent mattress adjusts the temperature of the first partition, which is currently set, to be consistent with the temperature of the second partition, which is currently set.

As another optional implementation manner, in the first aspect of this embodiment of the present application, after the intelligent mattress adjusts the currently set temperature of the first partition to be consistent with the currently set temperature of the second partition, the method further includes:

the smart mattress determines an electronic device of the first user;

and the intelligent mattress acquires the sleeping posture of the second user and sends the sleeping posture of the second user to the electronic equipment.

As a further optional implementation manner, in the first aspect of this embodiment of the present application, after the smart mattress sends the sleeping posture of the second user to the electronic device, the method further includes:

the intelligent mattress receives a control instruction which is sent by the electronic equipment and comprises a specified duration, and the control instruction is used for instructing the second user to execute the vibration operation of the specified duration so as to enable the second user to change the sleeping posture;

the intelligent mattress detects whether the second user wears the specified wearable equipment or not according to the control instruction; and if so, controlling the appointed wearable equipment to execute the vibration operation with the appointed time length so as to enable the second user to change the sleeping posture.

As a further optional implementation manner, in the first aspect of this embodiment of the application, if the smart mattress detects that the second user does not currently wear a specified wearable device, the method further includes:

the intelligent mattress detects whether the second user turns over from the second partition to the first partition; if not, executing the vibration operation with the specified duration on the second partition to enable the second user to change the sleeping posture; if yes, the vibration operation with the designated time length is executed on the first partition, so that the second user changes the sleeping posture.

The second aspect of the embodiment of this application discloses an intelligence mattress, intelligence mattress divides into left subregion and right subregion to the hardness of left subregion is different with the hardness of right subregion, intelligence mattress includes:

a first detection unit for detecting that a first user on a first partition gets up and leaves the first partition; wherein the first partition is the left partition or the right partition;

a first identification unit, configured to identify whether a second user exists on the second partition;

the first adjusting unit is used for adjusting the hardness of the first partition to be consistent with that of the second partition when the first identifying unit identifies that the second user exists on the second partition; the second partition is another partition of the left partition and the right partition other than the first partition.

As an optional implementation manner, in the second aspect of this embodiment of this application, the smart mattress further includes:

the second identification unit is used for identifying whether the currently set temperature of the first partition is consistent with the currently set temperature of the second partition after the first adjustment unit adjusts the hardness of the first partition to be consistent with the hardness of the second partition;

and the second adjusting unit is used for adjusting the temperature currently set by the first partition to be consistent with the temperature currently set by the second partition when the second identifying unit identifies that the temperature currently set by the first partition is inconsistent with the temperature currently set by the second partition.

As another optional implementation manner, in the second aspect of this embodiment of this application, the smart mattress further includes:

a determining unit, configured to determine the electronic device of the first user after the second adjusting unit adjusts the temperature currently set in the first partition to be consistent with the temperature currently set in the second partition;

the acquisition unit is used for acquiring the sleeping posture of the second user;

and the interaction unit is used for sending the sleeping posture of the second user to the electronic equipment.

As a further optional implementation manner, in the second aspect of the embodiment of the present application, the interaction unit is further configured to receive, after sending the sleeping posture of the second user to the electronic device, a control instruction sent by the electronic device and including a specified time length, where the control instruction is used to instruct the second user to perform a vibration operation of the specified time length to enable the second user to change the sleeping posture;

the intelligent mattress further comprises:

the second detection unit is used for detecting whether the second user wears the specified wearable equipment or not according to the control instruction;

and the control unit is used for controlling the specified wearable equipment to execute the vibration operation with the specified duration so as to enable the second user to change the sleeping posture when the second detection unit detects that the second user currently wears the specified wearable equipment.

As a further optional implementation manner, in the second aspect of this embodiment of the present application, the smart mattress further includes:

a third detecting unit, configured to detect whether the second user turns over from the second partition to the first partition when the second detecting unit detects that the second user does not currently wear a specified wearable device;

the control unit is further used for executing the vibration operation with the specified duration on the second partition to enable the second user to change the sleeping posture when the third detection unit detects that the second user does not turn over from the second partition to the first partition; or when the third detection unit detects that the second user turns over from the second partition to the first partition, the vibration operation with the specified duration is performed on the first partition so as to enable the second user to change the sleeping posture.

The third aspect of the embodiments of this application discloses an intelligent mattress, intelligent mattress divides into left subregion and right subregion to the softness and hardness of left subregion is different with the softness and hardness of right subregion, intelligent mattress includes:

a memory storing executable program code;

a processor coupled with the memory;

the processor calls the executable program code stored in the memory to execute the following steps:

detecting that a first user on a first partition gets up to leave the first partition; wherein the first partition is the left partition or the right partition;

identifying whether a second user is present on a second partition; if so, adjusting the hardness of the first partition to be consistent with that of the second partition; the second partition is another partition of the left partition and the right partition other than the first partition.

As an optional implementation manner, in the third aspect of this embodiment of the present application, after the processor adjusts the hardness of the first partition to be consistent with the hardness of the second partition, the following steps are further performed:

identifying whether the currently set temperature of the first partition is consistent with the currently set temperature of the second partition;

and if not, adjusting the currently set temperature of the first partition to be consistent with the currently set temperature of the second partition.

As another optional implementation manner, in the third aspect of the embodiment of the present application, after the processor adjusts the currently set temperature of the first partition to be consistent with the currently set temperature of the second partition, the following steps are further performed:

determining an electronic device of the first user;

and acquiring the sleeping posture of the second user, and sending the sleeping posture of the second user to the electronic equipment.

As a further optional implementation manner, in the third aspect of the embodiment of the present application, after the processor sends the sleeping posture of the second user to the electronic device, the following steps are further performed:

receiving a control instruction which is sent by the electronic equipment and comprises a specified duration, wherein the control instruction is used for instructing the second user to execute the vibration operation of the specified duration so as to enable the second user to change the sleeping posture;

detecting whether the second user currently wears a specified wearable device or not according to the control instruction; and if so, controlling the appointed wearable equipment to execute the vibration operation with the appointed time length so as to enable the second user to change the sleeping posture.

As a further optional implementation manner, in the third aspect of the embodiment of the present application, if the processor detects that the second user does not currently wear a specified wearable device, the processor further performs the following steps:

detecting whether the second user has turned over from the second partition to the first partition; if not, executing the vibration operation with the specified duration on the second partition to enable the second user to change the sleeping posture; if yes, the vibration operation with the designated time length is executed on the first partition, so that the second user changes the sleeping posture.

A fourth aspect of the embodiments of the present application discloses a storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements the steps in the partition hardness/softness adjustment method for an intelligent mattress in the first aspect of the embodiments of the present application or any optional implementation manner of the first aspect of the embodiments of the present application.

Compared with the prior art, the embodiment of the application has the following beneficial effects:

in an embodiment of the application, the smart mattress detects that a first user on a first partition gets up and leaves the first partition, and the first partition is a left partition or a right partition; furthermore, when the intelligent mattress identifies that a second user exists in the second partition, the hardness of the first partition is adjusted to be consistent with that of the second partition, the second partition is the other one of the left partition and the right partition except the first partition, and therefore when the second user turns over from the second partition to the first partition, the second user cannot feel uncomfortable due to the fact that the hardness of the second user is kept consistent. Therefore, by implementing the embodiment of the application, the user can be prevented from generating discomfort due to inconsistent hardness and softness when turning over from one of the left subarea and the right subarea of the intelligent mattress to the other subarea.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic flowchart of a first embodiment of a partition hardness and softness adjusting method for an intelligent mattress disclosed in an embodiment of the present application;

fig. 2 is a schematic flowchart of a second embodiment of a method for adjusting hardness of a partition of an intelligent mattress, disclosed in an embodiment of the present application;

FIG. 3 is a schematic diagram of a scenario in which a first user sets a temperature suitable for the first user for a first zone of a smart mattress in advance according to an embodiment of the present application;

fig. 4 is a schematic flowchart of a third embodiment of a partition hardness and softness adjusting method for an intelligent mattress disclosed in the embodiments of the present application;

FIG. 5 is a schematic structural diagram of a first embodiment of the intelligent mattress disclosed in the embodiments of the present application;

FIG. 6 is a schematic structural diagram of a second embodiment of the intelligent mattress disclosed in the embodiments of the present application;

FIG. 7 is a schematic structural diagram of a third embodiment of the intelligent mattress disclosed in the embodiments of the present application;

fig. 8 is a schematic structural diagram of a fourth embodiment of the intelligent mattress disclosed in the embodiments of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making any creative effort belong to the protection scope of the present application.

It should be noted that the terms "comprises" and "comprising," and any variations thereof, in the embodiments of the present application, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The embodiment of the application discloses a method for adjusting the hardness of a partition of an intelligent mattress and a related product, which can avoid the discomfort caused by inconsistent hardness when a user turns over from one partition of a left partition and a right partition of the intelligent mattress to the other partition. The following detailed description is made with reference to the accompanying drawings.

Referring to fig. 1, fig. 1 is a schematic flowchart of a partition hardness and softness adjusting method for an intelligent mattress according to a first embodiment of the present disclosure. In the method shown in fig. 1, the smart mattress is divided into a left zone and a right zone, and the hardness of the left zone is different from that of the right zone. For example, the intelligent mattress may be an intelligent air bag mattress, wherein the inflation saturation of the air bags in the left partition and the inflation saturation of the air bags in the right partition of the intelligent mattress may be individually controlled, that is, the hardness of the left partition (determined by the inflation saturation of the air bags in the left partition) may be individually controlled, and the hardness of the right partition (determined by the inflation saturation of the air bags in the right partition) may be individually controlled, so that the hardness of the left partition and the hardness of the right partition may be different, so as to meet the requirements of different hardness of the user in the left partition and the user in the right partition. As shown in fig. 1, the method comprises the steps of:

101. the smart mattress detects that a first user on the first zone gets up and leaves the first zone; wherein the first partition is a left partition or a right partition.

In some embodiments, the smart mattress may detect, via the camera, that a first user on the first zone gets up and leaves the first zone; alternatively, the smart mattress may detect that the first user in the first section gets up and leaves the first section by a sensor, for example, a pressure sensor may be provided in the first section to detect whether the first user is in a bed state or out of a bed state.

Generally, the left zone of the smart mattress is used for sleeping only one person, and the right zone is used for sleeping only another person, so the first user on the first zone can be understood as a user (such as a husband) who sleeps on the first zone.

102. The intelligent mattress identifies whether a second user exists on the second partition; if yes, go to step 103; if not, the flow is ended.

In some embodiments, the smart mattress may detect whether a second user is present on the second zone via the camera; alternatively, the smart mattress may detect whether the second user is present in the second zone by a sensor, for example, a pressure sensor may be provided in the second zone to detect whether the second user is in a bed state or out of bed state.

It will be appreciated that the second user on the second zone may be understood to be another user (e.g., a wife) who is sleeping on the second zone.

103. The intelligent mattress adjusts the hardness of the first partition to be consistent with that of the second partition; wherein the second partition is another partition of the left and right partitions other than the first partition.

In some embodiments, the intelligent mattress can compare the hardness of the first partition with the hardness of the second partition, and if the hardness of the first partition is greater than that of the second partition, the intelligent mattress can independently control the air bags in the first partition to be deflated until the inflation saturation of the air bags in the first partition is consistent with that of the air bags in the second partition, so that the hardness of the first partition is adjusted to be consistent with that of the second partition;

or if the hardness of the first partition is smaller than that of the second partition by comparison, the intelligent mattress can independently control the air bags in the first partition to be inflated until the inflation saturation of the air bags in the first partition is consistent with that of the air bags in the second partition, so that the hardness of the first partition is adjusted to be consistent with that of the second partition.

It can be seen that when the method shown in fig. 1 is implemented, when a second user rolls over from the second partition of the intelligent mattress to the first partition of the intelligent mattress, the hardness of the first partition and the hardness of the second partition are consistent, so that the second user does not feel uncomfortable. Therefore, the method shown in fig. 1 can be implemented to avoid the discomfort caused by inconsistent hardness and softness when a user (such as a second user) turns over from one of the left and right partitions of the intelligent mattress to the other partition.

Referring to fig. 2, fig. 2 is a schematic flowchart illustrating a method for adjusting hardness of a partition of an intelligent mattress according to a second embodiment of the present disclosure. In the method shown in fig. 2, the smart mattress is divided into a left zone and a right zone, and the hardness of the left zone is different from that of the right zone. As shown in fig. 2, the method comprises the steps of:

201. the smart mattress detects that a first user on the first zone gets up and leaves the first zone; wherein the first partition is a left partition or a right partition.

202. The intelligent mattress identifies whether a second user exists on the second partition; if yes, executing step 203 to step 204; if not, the flow is ended.

203. The intelligent mattress adjusts the hardness of the first partition to be consistent with that of the second partition; wherein the second partition is another partition of the left and right partitions other than the first partition.

By implementing the steps 201 to 203, the user (such as a second user) can be prevented from turning over from one of the left and right subareas of the intelligent mattress to the other subarea, which causes discomfort due to inconsistent hardness.

204. The intelligent mattress identifies whether the currently set temperature of the first partition is consistent with the currently set temperature of the second partition; if yes, ending the process; if not, go to step 205-step 207.

The currently set temperature of the first partition may be a temperature suitable for the first user and previously set for the first partition by the first user, and the currently set temperature of the second partition may be a temperature suitable for the second user and previously set for the second partition by the second user.

205. The intelligent mattress adjusts the temperature currently set in the first partition to be consistent with the temperature currently set in the second partition.

In some embodiments, an intelligent AIr chip (e.g., a multifunctional AIr-Circle intelligent AIr chip) may be built in the intelligent mattress, and the intelligent AIr chip may drive the circulation of cold and hot AIr through an AIr application technology to precisely adjust the currently set temperature of the first partition, so that the currently set temperature of the adjusted first partition is consistent with the currently set temperature of the second partition.

Wherein, this intelligence air chip passes through the cold heated air circulation operation of air application technology drive, and the realization mode of the current temperature that sets up of accurate regulation first subregion passes through the cold heated air circulation operation of air application technology drive with this intelligence air chip among the prior art, and the realization mode of the temperature of accurate regulation a certain mattress subregion is the same, and this application embodiment is not repeated.

By implementing the steps 204 to 205, the user (such as a second user) can be prevented from turning over from one of the left and right sub-areas of the intelligent mattress to the other sub-area due to inconsistent sub-area temperatures.

206. The smart mattress determines an electronic device of the first user.

Illustratively, the electronic device of the first user includes, but is not limited to, a cell phone, a tablet or a wrist electronic device of the first user.

207. The intelligent mattress acquires the sleeping posture of the second user and sends the sleeping posture of the second user to the electronic equipment of the first user.

The step 206 to the step 207 are implemented, so that the first user leaving the intelligent mattress can learn whether the sleeping posture of the second user on the intelligent mattress is correct, and then the second user can be timely reminded to change the sleeping posture when the sleeping posture of the second user is incorrect, so as to avoid the damage (such as strain of soft tissues at the neck, waist and back, obstruction of blood circulation, birth disorder, spinal damage and the like) to the body of the second user caused by the incorrect sleeping posture.

In some scenarios, a first user's left foot wears a first shoe and a first user's right foot wears a second shoe, wherein an inner side of the first shoe is opposite to an inner side of the second shoe, and the inner side of the first shoe is provided with a micro-projector and an inductive camera; further, the first shoe can be directly connected with the intelligent mattress in a wireless mode; accordingly, the manner in which the first user sets the temperature suitable for the first user for the first partition in advance may be:

the first user can move a first shoe worn by the first user to draw a first designated track (such as a triangular track) which is used for triggering the first shoe to output a temperature setting interface of the intelligent mattress; correspondingly, when the first shoe detects the first appointed track (such as a triangular track) drawn by the first shoe, a request message is sent to the intelligent mattress through wireless connection, and the request message is used for acquiring a temperature setting interface of the intelligent mattress; the first shoe can control the micro projector to project the temperature setting interface of the intelligent mattress after acquiring the temperature setting interface of the intelligent mattress sent by the intelligent mattress through wireless connection; the temperature setting interface of the intelligent mattress at least comprises a left partition option, a right partition option, a confirmation option, a temperature range bar and a temperature display frame; on the basis, when the first shoe detects that the toe cap of the second shoe sequentially touches a left partition option and a confirmation option included in the temperature setting interface of the intelligent mattress through the induction camera, the first shoe can recognize that the first user selects the first partition; further, when the first shoe detects that the toe cap of the second shoe touches a certain target temperature in the temperature range strip through the induction camera, the target temperature is displayed in the temperature display frame; furthermore, after the target temperature is displayed in the temperature display frame, when the first shoe detects that the toe cap of the second shoe touches the option of "confirmation" through the sensing camera, the first shoe can recognize that the target temperature displayed in the temperature display frame is the temperature suitable for the first user; accordingly, the first shoe may send a temperature setting instruction to the smart mattress that includes the target temperature and a partition number of the first partition (the partition number of the first partition is different from the partition number of the second partition); after the intelligent mattress receives the temperature setting instruction, the target temperature and the partition number of the first partition can be input into an intelligent AIr chip (such as a multifunctional AIr-Circle intelligent AIr chip) arranged in the intelligent mattress, so that the intelligent AIr chip can identify the first partition according to the partition number of the first partition, cold and hot AIr circulation operation is driven through an AIr application technology, the currently set temperature of the first partition is accurately adjusted to be the target temperature, and the first user can set the temperature suitable for the first user for the first partition in advance.

For example, as shown in fig. 3, after the first shoe worn by the first user is acquired to the temperature setting interface of the smart mattress sent by the smart mattress through a wireless connection (indicated by a dashed double arrow), the micro projector arranged inside the first shoe may be controlled to project (the dashed line indicates a projection range) the temperature setting interface of the smart mattress; the temperature setting interface of the intelligent mattress can comprise a left partition option, a right partition option, a confirmation option, a temperature range bar of 25-40 ℃ and a temperature display frame; on the basis, when the first shoe detects that the toe cap of the second shoe sequentially touches the temperature setting interface of the intelligent mattress through the induction camera, the temperature setting interface comprises a left partition option and a confirmation option, the first shoe can recognize that the first user selects the first partition; further, when the toe cap of the first shoe is detected to be in contact with the target temperature of 30 ℃ in the temperature range of 25-40 ℃ by the induction camera, the target temperature of 30 ℃ is displayed in the temperature display frame; furthermore, after the target temperature of 30 ℃ is displayed in the temperature display frame, when the first shoe detects that the toe of the second shoe touches the "confirmation" option through the induction camera, the first shoe can recognize that the target temperature of 30 ℃ displayed in the temperature display frame is a temperature suitable for the first user; accordingly, the first shoe may send a temperature setting instruction including the target temperature of 30 ℃ and a partition number of the first partition to the smart mattress; after the intelligent mattress receives the temperature setting instruction, the target temperature of 30 ℃ and the partition number of the first partition can be input into an intelligent AIr chip (such as a multifunctional AIr-Circle intelligent AIr chip) arranged in the intelligent mattress, so that the intelligent AIr chip can identify the first partition according to the partition number of the first partition, the cold and hot AIr circulation operation is driven through an AIr application technology, the currently set temperature of the first partition is accurately adjusted to be the target temperature of 30 ℃, and the first user can set the temperature suitable for the first user for the first partition in advance.

By the implementation of the mode, the first user can conveniently and quickly preset the temperature suitable for the first user for the first partition without sending a voice command or manually operating. Particularly, when the first user is a user who has difficulty in pronunciation and/or a user who has difficulty in handling, the above manner can further improve the experience when the first user sets the temperature suitable for the first user for the first partition in advance.

In some embodiments, the manner of the temperature suitable for the second user, which is set for the second partition in advance by the second user, may be similar to the manner of the temperature suitable for the first user, which is set for the first partition in advance by the first user, and is not described herein again.

In some embodiments, the manner in which the first shoe worn by the first user establishes the direct wireless connection with the smart mattress may be as follows:

after entering the coverage range of the hot spot of the intelligent mattress, the first user can trigger the first shoe worn by the left foot of the first user to scan the unique identification of the hot spot around the first user; for example, after entering the coverage area of the hot spot of the smart mattress, the first user may move the first shoe worn by his left foot to scribe a second designated track (e.g., a square track) for triggering the first shoe to scan the unique identification of the hot spot around; when the second appointed track drawn by the corresponding first shoe is detected, the unique identification of the hot spot around the first shoe is detected and scanned; and a micro projector disposed on an inner side of the first shoe may be controlled to project a hot spot selection interface, the hot spot selection interface including a unique identifier of the scanned surrounding hot spot and a "confirmation" option; on the basis, when the first shoe detects that the toe cap of the second shoe sequentially touches the unique identification of the hot spot of the intelligent mattress and the 'confirmation' option in the unique identifications of the hot spots around the first shoe through the induction camera, the first shoe can identify the hot spot of the first user for selecting the intelligent mattress; controlling the micro projector to project a key input interface, wherein the key input interface comprises a plurality of characters to be selected and a key display frame; on the basis, when the first shoe detects that the toe cap of the second shoe touches part or all of the characters to be selected in the characters to be selected included in the key input interface through the induction camera, the touched part or all of the characters to be selected are sequenced and spliced into the verification key according to the touching sequence of the characters to be selected and displayed in the key display frame; after the touched part or all of the characters to be selected are sequenced, spliced and displayed in a key display frame to form a verification key, when a first shoe detects that the toe cap of a second shoe touches a 'confirmation' option included in a hotspot selection interface through an induction camera, a hotspot access request containing a unique identifier of a hotspot of the intelligent mattress and the verification key is broadcasted; correspondingly, when the intelligent mattress receives the hotspot access request and identifies the unique identifier of the hotspot of the intelligent mattress, whether the verification key is consistent with the legal access key corresponding to the hotspot of the intelligent mattress is verified, and if so, the first shoe is allowed to be accessed to the hotspot of the intelligent mattress, so that the direct wireless connection between the first shoe and the intelligent mattress is established.

The implementation of the above mode enables the first user to establish a direct wireless connection between the first shoe and the intelligent mattress without voice command or manual operation. In particular, when the first user is a user with difficulty in pronouncing and/or a user with difficulty in handling, the above manner can further improve the experience of the first user in establishing a direct wireless connection between the first shoe of the first user and the intelligent mattress.

In some embodiments, in step 206, the electronic device of the first user determined by the smart mattress may be a first shoe worn by the first user; correspondingly, in step 207, the manner in which the smart mattress sends the sleeping posture of the second user to the electronic device of the first user may be:

the intelligent mattress detects whether a first shoe worn by a first user is still directly and wirelessly connected with the intelligent mattress, and if so, the sleeping posture of a second user is directly sent to the first shoe worn by the first user; if not, the intelligent mattress sends the unique identification (such as the mac address of the first shoe) of the first shoe worn by the first user and the sleeping posture of the second user to the cloud end, so that the cloud end sends the sleeping posture of the second user to the first shoe according to the unique identification of the first shoe; correspondingly, the first shoe worn by the first user acquires the sleeping posture of the second user sent by the intelligent mattress or the cloud end, and controls the micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch.

The above embodiment is implemented so that the first user can directly view the sleeping posture of the second user.

In some embodiments, after the first shoe worn by the first user acquires the sleeping posture of the second user sent by the smart mattress or the cloud, the following steps may be further performed:

a first shoe worn by a first user performs a prompt operation for prompting that the first user can watch the sleeping posture of a second user; for example, the prompt operation may be a vibration prompt operation or a light effect prompt operation;

when the first shoe worn by the first user detects the movement of the first shoe, a third specified track (such as a circular track) is used for triggering the first shoe to control a micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user;

and the first shoe worn by the first user executes the step of controlling the micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch according to the third designated track.

By the implementation of the embodiment, the accuracy of the first shoe worn by the first user for controlling the micro projector to project the sleeping posture of the second user can be improved.

Referring to fig. 4, fig. 4 is a schematic flowchart of a third embodiment of a partition hardness and softness adjusting method for an intelligent mattress disclosed in the embodiment of the present application. In the method shown in fig. 4, the smart mattress is divided into a left zone and a right zone, and the hardness of the left zone is different from that of the right zone. As shown in fig. 4, the method comprises the steps of:

here, steps 401 to 407 are the same as steps 201 to 207 in the previous embodiment, and are not repeated here.

In some embodiments, in step 406, the electronic device of the first user determined by the smart mattress may be a first shoe worn by the first user; correspondingly, in step 407, the manner in which the smart mattress sends the sleeping posture of the second user to the electronic device of the first user may be:

a first shoe worn by a first user performs a prompting operation, wherein the prompting operation is used for prompting that the first user can watch the sleeping posture of a second user; for example, the prompt operation may be a vibration prompt operation or a light effect prompt operation;

and the first shoe worn by the first user executes the step of controlling a micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch according to the third appointed track.

By implementing the embodiment, the accuracy of the first shoe worn by the first user for controlling the micro projector to project the sleeping posture of the second user can be improved.

408. The intelligent mattress receives a control instruction which is sent by the electronic equipment and comprises a specified duration, and the control instruction is used for instructing a second user to execute a vibration operation with the specified duration so as to enable the second user to change the sleeping posture.

In some embodiments, after the first shoe worn by the first user controls the micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch, the interval duration between two tramples occurring in front of and behind the first shoe can be detected as the specified duration, and a control instruction including the specified duration is sent to the intelligent mattress directly or through a cloud.

409. The intelligent mattress detects whether the second user wears the specified wearable equipment or not according to the control instruction; if yes, go to step 410; if not, go to step 411.

In some embodiments, the smart mattress sends a detection instruction to a specified wearable device according to the control instruction, wherein the detection instruction is used for instructing the specified wearable device to detect whether a second user currently wears the specified wearable device; the intelligent mattress can receive the detection result sent by the appointed wearable equipment and identify and detect whether the second user wears the appointed wearable equipment or not according to the detection result; if yes, go to step 410; if not, go to step 411.

410. The intelligent mattress controls the appointed wearable equipment to execute the vibration operation with the appointed time length so as to enable the second user to change the sleeping posture, and the process is ended.

In some embodiments, the control instructions may further include an average force value of two tramples occurring in front of and behind a first shoe worn by the first user; accordingly, the controlling, by the smart mattress, the designated wearable device to perform the vibration operation for the designated duration to cause the second user to change the sleeping posture may include:

the intelligent mattress determines the corresponding target vibration strength according to the average force value; the target vibration strength is in a direct proportional relation with the average force value, namely the larger the average force value is, the larger the target vibration strength is; conversely, the smaller the average force value is, the smaller the target vibration force is;

and the intelligent mattress controls the appointed wearable equipment to execute the vibration operation with the duration of the appointed duration and the vibration strength of the target vibration strength so as to enable the second user to change the sleeping posture.

411. The intelligent mattress detects whether a second user turns over from the second partition to the first partition; if not, go to step 412; if yes, go to step 413.

412. The intelligent mattress executes the vibration operation with the specified duration to the second partition so as to enable the second user to change the sleeping posture, and the process is ended.

In some embodiments, the control instructions may further include an average force value of two tramples occurring in front of and behind a first shoe worn by the first user; accordingly, the intelligent mattress performing the vibration operation for the designated duration on the second partition to enable the second user to change the sleeping posture may include:

the intelligent mattress determines the corresponding target vibration strength according to the average force value; wherein, the target vibration strength is in direct proportion relation with the average force value;

and the intelligent mattress executes the vibration operation with the specified duration and the target vibration strength on the second partition so as to enable the second user to change the sleeping posture.

In some embodiments, a massage head may be disposed under the second partition of the smart mattress, and accordingly, the smart mattress may control the massage head disposed under the second partition to perform a vibration operation with a vibration strength as the target vibration strength for the specified duration on the second partition, so as to change the sleeping posture of the second user.

413. The intelligent mattress performs the vibration operation on the first partition for the designated time length to enable the second user to change the sleeping posture.

In some embodiments, the control instructions may further include an average force value of two tramples occurring in front of and behind a first shoe worn by the first user; accordingly, the performing, by the smart mattress, the vibration operation for the designated duration on the first partition to change the sleeping posture of the second user may include:

and the intelligent mattress executes the vibration operation with the duration of the specified duration and the vibration strength of the target vibration strength on the first partition so as to enable the second user to change the sleeping posture.

In some embodiments, a massage head may be disposed under the first partition of the smart mattress, and accordingly, the smart mattress may control the massage head disposed under the first partition to perform a vibration operation with a vibration force as the target vibration force for the specified duration on the first partition, so as to change the sleeping posture of the second user.

In step 408 to step 413, the intelligent mattress can send a control instruction according to the electronic device of the first user who leaves the intelligent mattress, so as to effectively remind the second user of changing the sleeping posture, thereby avoiding the damage to the body of the second user (such as strain of soft tissues at the neck, waist and back, blood circulation blockage, birth defects, spinal damage, etc.) caused by incorrect sleeping posture.

In addition, the method shown in fig. 4 can be implemented to avoid the discomfort caused by inconsistent softness and hardness when a user (such as a second user) turns over from one of the left and right partitions of the intelligent mattress to the other partition.

Referring to fig. 5, fig. 5 is a schematic structural diagram of a first embodiment of the intelligent mattress disclosed in the embodiment of the present application. The intelligent mattress shown in fig. 5 can be divided into a left partition and a right partition, and the hardness of the left partition is different from that of the right partition. As shown in fig. 5, the intelligent mattress comprises the following steps:

a first detecting unit 501 for detecting that a first user on a first partition gets up and leaves the first partition; wherein the first partition is a left partition or a right partition;

a first identifying unit 502, configured to identify whether a second user exists on the second partition;

a first adjusting unit 503, configured to adjust the hardness of the first partition to be consistent with the hardness of the second partition when the first identifying unit 502 identifies that the second user exists on the second partition; the second partition is another partition of the left and right partitions other than the first partition.

For an implementation manner that the first adjusting unit 503 adjusts the hardness of the first partition to be consistent with the hardness of the second partition, reference may be made to step 103 in the foregoing embodiment, which is not described in detail in this embodiment of the present application.

It can be seen that, when the intelligent mattress shown in fig. 5 is applied, when a second user turns over from the second partition of the intelligent mattress to the first partition of the intelligent mattress, the hardness of the first partition and the hardness of the second partition are consistent, so that the second user does not feel uncomfortable. Therefore, when the intelligent mattress shown in fig. 5 is applied, the discomfort caused by inconsistent softness and hardness when a user (such as a second user) turns over from one of the left and right subareas of the intelligent mattress to the other subarea can be avoided.

Referring to fig. 6, fig. 6 is a schematic structural diagram of a second embodiment of the intelligent mattress disclosed in the embodiments of the present application. Wherein the intelligent mattress shown in fig. 6 is optimized from the intelligent mattress shown in fig. 5. Compared to the smart mattress shown in fig. 5, the smart mattress shown in fig. 6 may further include:

a second identifying unit 504, configured to identify whether the currently set temperature of the first partition is consistent with the currently set temperature of the second partition after the first adjusting unit 503 adjusts the hardness of the first partition to be consistent with the hardness of the second partition;

a second adjusting unit 505, configured to adjust the temperature currently set by the first partition to be consistent with the temperature currently set by the second partition when the second identifying unit 504 identifies that the temperature currently set by the first partition is inconsistent with the temperature currently set by the second partition.

In some embodiments, the second adjusting unit 505 may be built-in with an intelligent AIr chip (e.g., a multifunctional AIr-Circle intelligent AIr chip), and the intelligent AIr chip may drive the cold and hot AIr circulation operation through an AIr application technology, so as to precisely adjust the currently set temperature of the first partition, so that the adjusted currently set temperature of the first partition is consistent with the currently set temperature of the second partition.

In some embodiments, the smart mattress shown in fig. 6 further comprises:

a determining unit 506, configured to determine the electronic device of the first user after the second adjusting unit 505 adjusts the temperature currently set in the first partition to be consistent with the temperature currently set in the second partition;

an obtaining unit 507, configured to obtain a sleeping posture of a second user;

an interaction unit 508, configured to send the sleeping posture of the second user to the electronic device of the first user.

In some embodiments, the electronic device of the first user determined by the determining unit 506 may be a first shoe worn by the first user; accordingly, the way for the interaction unit 508 to send the sleeping posture of the second user to the electronic device of the first user may be:

the interaction unit 508 detects whether the first shoe worn by the first user is still directly wirelessly connected to the intelligent mattress, and if so, directly sends the sleeping posture of the second user to the first shoe worn by the first user; if not, the interaction unit 508 sends the unique identifier of the first shoe worn by the first user (such as the mac address of the first shoe) and the sleeping posture of the second user to the cloud, so that the cloud sends the sleeping posture of the second user to the first shoe according to the unique identifier of the first shoe; correspondingly, the first shoe worn by the first user acquires the sleeping posture of the second user sent by the intelligent mattress or the cloud end, and controls the micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch.

The intelligent mattress shown in fig. 6 can avoid the discomfort caused by the inconsistent temperature of the zones when a user (such as a second user) turns over from one zone to the other zone of the left and right zones of the intelligent mattress.

In addition, the intelligent mattress shown in fig. 6 is applied, so that a first user leaving the intelligent mattress can learn whether the sleeping posture of a second user on the intelligent mattress is correct, and then the second user can be reminded to change the sleeping posture when the sleeping posture of the second user is incorrect, so as to avoid the damage (such as neck, waist and back soft tissue strain, blood circulation obstruction, birth disorder, spinal damage and the like) to the body of the second user caused by the incorrect sleeping posture.

Referring to fig. 7, fig. 7 is a schematic structural diagram of a third embodiment of the intelligent mattress disclosed in the embodiment of the present application. Wherein the intelligent mattress shown in fig. 7 is optimized from the intelligent mattress shown in fig. 6. In the smart mattress shown in fig. 7, the interaction unit 508 is further configured to receive a control instruction sent by the electronic device of the first user and including a specified duration after sending the sleeping posture of the second user to the electronic device of the first user, where the control instruction is used to instruct the second user to perform a vibration operation for the specified duration to change the sleeping posture of the second user;

accordingly, the smart mattress shown in fig. 6 may further include:

a second detecting unit 509, configured to detect whether the second user currently wears a designated wearable device according to the control instruction;

a control unit 510, configured to, when the second detection unit 509 detects that the second user currently wears the specified wearable device, control the specified wearable device to perform a vibration operation for the specified time period to enable the second user to change the sleeping posture.

In some embodiments, the second detecting unit 509 may send a detection instruction to the designated wearable device according to the control instruction, where the detection instruction is used to instruct the designated wearable device to detect whether the second user currently wears the designated wearable device; and, the second detecting unit 509 may receive the detection result sent by the specified wearable device, and recognize and detect whether the second user currently wears the specified wearable device according to the detection result.

In some embodiments, the control instructions may further include an average force value of two tramples occurring in front of and behind a first shoe worn by the first user; accordingly, the controlling unit 510 controlling the designated wearable device to perform the vibration operation for the designated duration to make the second user change the sleeping posture may include:

the control unit 510 determines a corresponding target vibration strength according to the average force value; the target vibration strength is in a direct proportional relation with the average force value, namely the larger the average force value is, the larger the target vibration strength is; conversely, the smaller the average force value is, the smaller the target vibration force is;

and the control unit 510 controls the designated wearable device to perform a vibration operation with a vibration strength as the target vibration strength and with a duration as the designated duration, so as to enable the second user to change the sleeping posture.

In some embodiments, the smart mattress shown in fig. 7 further comprises:

a third detecting unit 511, configured to detect whether the second user turns over from the second partition to the first partition when the second detecting unit 509 detects that the second user does not currently wear the specified wearable device;

the control unit 510 is further configured to, when the third detecting unit 511 detects that the second user does not turn over from the second partition to the first partition, perform a vibration operation on the second partition for the specified time length to enable the second user to change the sleeping posture; alternatively, when the third detecting unit 511 detects that the second user turns over from the second partition to the first partition, the vibration operation for the specified time period is performed on the first partition to make the second user change the sleeping posture.

In some embodiments, the control instructions may further include an average force value of two tramples occurring before and after a first shoe worn by the first user; accordingly, the control unit 510 performing the vibration operation for the designated time period on the second partition to make the second user change the sleeping posture may include:

the control unit 510 determines a corresponding target vibration strength according to the average force value; wherein, the target vibration strength is in direct proportion relation with the average force value;

and the control unit 510 performs a vibration operation with a vibration force being the target vibration force for the second partition for the specified time length to change the sleeping posture of the second user.

In some embodiments, the performing, by the control unit 510, the vibration operation for the specified duration on the first partition to cause the second user to change the sleeping posture may include:

the control unit 510 determines a corresponding target vibration strength according to the average force value; wherein, the target vibration strength is in direct proportion relation with the average strength value;

and the control unit 510 performs a vibration operation with the specified duration and the target vibration strength on the first partition, so that the second user changes the sleeping posture.

When the intelligent mattress shown in fig. 6 is applied, a control instruction can be sent according to the electronic equipment of the first user away from the intelligent mattress, so that the second user can be effectively reminded to change the sleeping posture, and the body of the first user is prevented from being damaged (such as neck, waist and back soft tissue strain, blood circulation blockage, birth defects, spinal damage and the like) due to incorrect sleeping posture.

Referring to fig. 8, fig. 8 is a schematic structural diagram of a fourth embodiment of the intelligent mattress disclosed in the embodiments of the present application. The intelligent mattress shown in fig. 8 can be divided into a left partition and a right partition, and the hardness of the left partition is different from that of the right partition. As shown in fig. 8, the smart mattress includes:

a memory 801 in which executable program code is stored;

a processor 802 coupled with the memory 801;

the processor 802 calls the executable program code stored in the memory 801 to execute the following steps:

detecting that a first user on a first zone gets up to leave the first zone; wherein the first partition is a left partition or a right partition;

identifying whether a second user is present on the second partition; if the first partition is existed, the hardness of the first partition is adjusted to be consistent with that of the second partition; the second partition is another partition other than the first partition among the left partition and the right partition.

In some embodiments, after the processor 802 adjusts the hardness of the first partition to be consistent with the hardness of the second partition, the following steps are further performed:

By implementing the embodiment, the discomfort caused by inconsistent partition temperatures when a user (such as a second user) turns over from one of the left partition and the right partition of the intelligent mattress to the other partition can be avoided.

In some embodiments, after the processor 802 adjusts the temperature currently set in the first partition to be consistent with the temperature currently set in the second partition, the following steps are also performed:

determining an electronic device of a first user;

and acquiring the sleeping posture of the second user, and sending the sleeping posture of the second user to the electronic equipment of the first user.

The first user leaving the intelligent mattress can learn whether the sleeping posture of the second user on the intelligent mattress is correct or not, and then the second user can be reminded to change the sleeping posture when the sleeping posture of the second user is incorrect, so that the body of the second user is prevented from being damaged (such as neck, waist and back soft tissue strain, blood circulation obstruction, birth disorder, spinal damage and the like) due to the incorrect sleeping posture.

In some embodiments, the electronic device of the first user determined by the processor 802 may be a first shoe worn by the first user; accordingly, the way the processor 802 sends the sleeping posture of the second user to the electronic device of the first user may be:

detecting whether a first shoe worn by a first user is still directly and wirelessly connected with the intelligent mattress, and if so, directly sending the sleeping posture of a second user to the first shoe worn by the first user; if not, sending the unique identification (such as the mac address of the first shoe) of the first shoe worn by the first user and the sleeping posture of the second user to the cloud end, so that the cloud end sends the sleeping posture of the second user to the first shoe according to the unique identification of the first shoe; correspondingly, the first shoe worn by the first user acquires the sleeping posture of the second user sent by the intelligent mattress or the cloud end, and controls the micro projector arranged on the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch.

In some embodiments, after the processor 802 sends the sleeping posture of the second user to the electronic device of the first user, the following steps are further performed:

receiving a control instruction which is sent by electronic equipment of a first user and comprises a specified duration, wherein the control instruction is used for instructing a second user to execute vibration operation of the specified duration so as to enable the second user to change the sleeping posture;

detecting whether a second user wears a specified wearable device or not according to the control instruction; if yes, controlling the designated wearable device to execute the vibration operation of the designated duration so as to enable the second user to change the sleeping posture.

In some embodiments, after the first shoe worn by the first user controls the micro projector arranged at the inner side of the first shoe to project the sleeping posture of the second user for the first user to watch, the interval duration between two tramples occurring at the front and back of the first shoe can be detected as a specified duration, and a control instruction comprising the specified duration is sent to the intelligent mattress.

In some embodiments, the control instructions may further include an average force value of two tramples occurring in front of and behind a first shoe worn by the first user; accordingly, the processor 802 controlling the designated wearable device to perform the vibration operation for the designated duration to cause the second user to change the sleeping posture may include:

determining corresponding target vibration strength according to the average force value; the target vibration strength is in a direct proportional relation with the average force value, namely the larger the average force value is, the larger the target vibration strength is; conversely, the smaller the average force value is, the smaller the target vibration force is;

and controlling the specified wearable equipment to execute vibration operation with the execution time length of the specified time length and the vibration strength of the target vibration strength so as to enable the second user to change the sleeping posture.

In some embodiments, if the processor 802 detects that the second user is not currently wearing the designated wearable device, the processor 802 further performs the following steps:

detecting whether a second user turns over from the second partition to the first partition; if not, executing the vibration operation with the specified duration on the second partition to enable the second user to change the sleeping posture; if yes, the vibration operation with the specified time length is executed on the first partition so that the second user can change the sleeping posture.

According to the implementation of the implementation method, the control instruction can be sent according to the electronic equipment of the first user leaving the intelligent mattress, and the second user is effectively reminded to change the sleeping posture, so that the body of the first user is prevented from being damaged by the incorrect sleeping posture (such as strain of soft tissues of neck, waist and back, blood circulation obstruction, birth disorder, spinal damage and the like).

In addition, by applying the intelligent mattress shown in fig. 8, the discomfort caused by inconsistent softness and hardness when a user (such as a second user) turns over from one of the left and right subareas of the intelligent mattress to the other subarea can be avoided.

The embodiments of the present application further disclose a storage medium having a computer program stored thereon, where the computer program is executed by a processor to implement all or part of the steps in the previous method embodiments.

The method for adjusting the hardness of the zones of the intelligent mattress, the intelligent mattress and the storage medium disclosed in the embodiment of the application are introduced in detail, specific examples are applied in the text to explain the principle and the implementation mode of the application, and the description of the embodiment is only used for helping to understand the method and the core idea of the application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the application.

Claims

1. A method for adjusting the hardness of a partition of an intelligent mattress, wherein the intelligent mattress is divided into a left partition and a right partition, and the hardness of the left partition is different from that of the right partition, the method comprising the following steps:

2. The partition hardness-adjustment method according to claim 1, wherein after the intelligent mattress adjusts the hardness of the first partition to be consistent with the hardness of the second partition, the method further comprises:

3. The partition hardness-adjustment method according to claim 2, wherein after the intelligent mattress adjusts the temperature currently set in the first partition to be consistent with the temperature currently set in the second partition, the method further comprises:

the smart mattress determines an electronic device of the first user;

4. The partition softness and hardness adjusting method according to claim 3, wherein after the smart mattress sends the electronic device the sleeping posture of the second user, the method further comprises:

the intelligent mattress detects whether the second user wears the specified wearable equipment or not according to the control instruction; and if so, controlling the designated wearable equipment to execute the vibration operation of the designated duration so as to enable the second user to change the sleeping posture.

5. The method of claim 4, wherein if the smart mattress detects that the second user is not currently wearing a designated wearable device, the method further comprises:

6. A smart mattress that is divided into a left zone and a right zone, and the softness or hardness of the left zone is different from the softness or hardness of the right zone, the smart mattress comprising:

the first adjusting unit is used for adjusting the hardness of the first partition to be consistent with that of the second partition when the first identifying unit identifies that the second user exists in the second partition; the second partition is another partition of the left partition and the right partition other than the first partition.

7. An intelligent mattress, the intelligent mattress being divided into a left zone and a right zone, and the softness and hardness of the left zone being different from the softness and hardness of the right zone, the intelligent mattress comprising:

a memory storing executable program code;

a processor coupled with the memory;

8. The intelligent mattress according to claim 7, wherein after the processor adjusts the softness or hardness of the first partition to be consistent with the softness or hardness of the second partition, the following steps are further performed:

identifying whether the temperature currently set by the first partition is consistent with the temperature currently set by the second partition;

9. The smart mattress according to claim 8, wherein after the processor adjusts the temperature currently set in the first zone to coincide with the temperature currently set in the second zone, the following steps are further performed:

determining an electronic device of the first user;

10. The smart mattress of claim 9, wherein after the processor sends the sleeping posture of the second user to the electronic device, the following steps are further performed:

detecting whether the second user currently wears a specified wearable device or not according to the control instruction; and if so, controlling the designated wearable equipment to execute the vibration operation of the designated duration so as to enable the second user to change the sleeping posture.

11. The smart mattress of claim 10, wherein if the processor detects that the second user is not currently wearing a designated wearable device, the processor further performs the steps of:

detecting whether said second user has turned over from said second partition to said first partition; if not, executing the vibration operation with the specified duration on the second partition to enable the second user to change the sleeping posture; if yes, the vibration operation of the designated time length is executed on the first partition, so that the second user can change the sleeping posture.

12. A storage medium having a computer program stored thereon, wherein the computer program, when executed by a processor, implements the steps in the method for partitioned softness/hardness adjustment of a smart mattress according to any one of claims 1 to 5.