AI agent-based controllable medical and patient dual-purpose pillow system and method
The AI-driven, pressure-controlled pulse pillow system for both doctors and patients solves the problem that traditional pulse pillows cannot meet the comfort and stability requirements of both parties. It achieves a dual-use structure for both doctors and patients, reduces doctor fatigue, and improves the accuracy and comfort of pulse diagnosis, making it suitable for various diagnostic and treatment scenarios.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- THE SIXTH MEDICAL CENT OF THE CHINESE PEOPLES LIBERATION ARMY GENERAL HOSPITAL
- Filing Date
- 2026-03-31
- Publication Date
- 2026-06-05
Smart Images

Figure CN122140201A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of medical device technology, and more specifically, to a medical device-patient dual-use pulse pillow system and method based on an AI intelligent agent with controllable support and pressure. Background Technology
[0002] Currently, palpation is a crucial component of the four diagnostic methods in Traditional Chinese Medicine (TCM). Doctors assess the flow of Qi and blood and the function of internal organs by palpating the radial artery at the patient's wrist. In clinical practice, pulse pillows are commonly used as supportive aids to ensure the patient's wrist is in a stable, relaxed, and appropriately positioned state, improving the standardization and comfort of pulse diagnosis. However, with the continuous increase in TCM outpatient visits and the prevalence of continuous pulse diagnosis, both doctors and patients have higher demands for the comfort, stability, and intelligence of pulse diagnosis aids. Traditional pulse pillow structures are no longer sufficient to meet the needs of modern TCM diagnosis and treatment.
[0003] Existing pulse pillows are generally of a single structure and are intended for patient use only. Their height and shape are usually fixed or adjusted using simple pads. They do not take into account the ergonomic needs of doctors who often need to lean forward, have their arms suspended, or maintain a fixed posture during long-term continuous pulse diagnosis. The height of the pulse pillow does not match the doctor's sitting posture or height, which can easily cause occupational strain during long-term use. Their functionality is relatively limited.
[0004] Some pulse pillows have adjustable height, but their adjustment methods are inaccurate, cumbersome, and lack intelligent adjustment solutions that take into account the needs of both doctors and patients. They fail to effectively combine artificial intelligence with the height adjustment of pulse pillow products and cannot intelligently match according to the differences in body shape between doctors and patients. Patients still need to actively adjust their wrist posture to adapt to the height of the pulse pillow, which directly affects the natural state of the pulse and reduces the accuracy of the pulse diagnosis results. Summary of the Invention
[0005] To address this issue, the present invention provides a pulse pillow system and method based on AI intelligent agents with controllable support and pressure for both medical staff and patients, in order to solve the problems in the prior art where pulse pillows only support unilateral use and where the accuracy is affected by the pulse pillow.
[0006] To achieve the above objectives, the present invention provides the following technical solution: A method for using a pulse pillow with controllable support and pressure based on an AI agent, suitable for both medical staff and patients, includes the following steps: Collect physical parameters and treatment posture parameters from both doctors and patients; Based on the collected parameters, the optimal height of the pulse pillow for both doctor and patient is calculated using artificial intelligence algorithms. Convert altitude data into barometric pressure control data; Based on the air pressure regulation data, control the gas cylinder to inflate or deflate the air bag; Simultaneously adjust the patient's pulse pillow and the doctor's pulse pillow to the target height; Maintaining the pulse pillows of both the doctor and patient at a high level of stability is essential for completing the pulse diagnosis procedure. After the pulse diagnosis, depressurize and reset the airbag.
[0007] Based on the above technical solution, the present invention is further described as follows: As a further aspect of the present invention, The collection of physical parameters and treatment posture parameters from both the doctor and the patient specifically includes: The system obtains several body and posture data of doctors, including height, weight, arm length, and common sitting posture, through the input terminal. At the same time, it also obtains data of patients' height, wrist circumference, and natural forearm posture. After data collection is completed, it is transmitted to the AI intelligent processor. The AI intelligent processor standardizes the data, removes outliers and unifies the data format, providing an accurate input basis for subsequent calculations. This allows for a comprehensive understanding of individual characteristics of doctors and patients, ensuring a high degree of matching and adherence to actual needs in the subsequent process. The optimal height data for the doctor-patient pulse pillow is calculated using artificial intelligence algorithms based on the collected parameters, specifically including: The processed patient parameters and doctor parameters are synchronously input into a preset collaborative calculation model. Based on ergonomic rules and pulse diagnosis operation standards, the model generates the patient's pulse pillow height matching value and the doctor's pulse pillow height matching value respectively. The model outputs the optimal height combination for both sides of the doctor and patient through a collaborative optimization algorithm, such as the required support height difference at the bottom of the arm when the doctor's fingers contact the patient's wrist.
[0008] As a further aspect of the present invention, The conversion of altitude data into barometric pressure control data specifically includes: Corresponding to the patient's pulse pillow and the doctor's pulse pillow, each has a pre-installed airbag. The control system has a pre-stored model of the correspondence between the pulse pillow height and the airbag pressure. Based on the AI intelligent processor, the target height value is mapped to the corresponding inflation or deflation volume, generating a continuous air pressure control command sequence. The command sequence includes inflation rate, inflation duration, and air pressure threshold parameters to ensure accurate execution of subsequent airway control.
[0009] As a further aspect of the present invention, The conversion of altitude data into barometric pressure control data further includes: The pre-installed airbags of the doctor's pulse pillow and / or the patient's pulse pillow are set as partitioned airbags, which include at least one elbow portion airbag and at least one wrist portion airbag. At least one elbow portion airbag and at least one wrist portion airbag each have an internal pressure monitoring component and a corresponding target air pressure, and at least one elbow portion airbag and at least one wrist portion airbag are inflated independently.
[0010] As a further aspect of the present invention, The conversion of altitude data into barometric pressure control data further includes: Establish a mechanical collaborative verification architecture; The mechanical collaborative verification architecture is configured as a first axis corresponding to the upper edge side of the wrist airbag, a second axis corresponding to the upper edge side of the elbow airbag, and a telescopic ruler that is respectively connected between the first axis and the second axis. The telescopic ruler is used to mechanically measure the distance between the two axes in real time. When applied, the target value range of the telescopic ruler set on the specific doctor's pulse pillow is first determined based on the corresponding target air pressure and height of the elbow and wrist air bladders. Then, under normal use, the accuracy of the support height of the wrist and elbow is checked by determining whether the telescopic ruler is within the target value range. It can also detect and adjust the internal pressure monitoring component in a timely manner from the outside when the performance deteriorates. The preset visual monitoring component corresponds to the telescopic ruler. The visual monitoring component is connected to the AI intelligent processor through a circuit, thereby automatically monitoring the mechanical changes.
[0011] As a further aspect of the present invention, The operation of inflating or deflating the gas cylinder into the gas bag based on the gas pressure regulation data specifically includes: After receiving the command, the gas path control module opens the gas supply channel of the gas storage cylinder and controls the inflation flow and total supply of the pre-set airbags inside the patient's pulse pillow and the doctor's pulse pillow according to the command parameters. At the same time, during the control process, the air pressure signals inside the two sets of airbags are collected in real time. The real-time air pressure inside the two sets of airbags is compared with the corresponding air pressure threshold and closed-loop correction is performed to prevent the height deviation caused by excessive or insufficient air pressure.
[0012] As a further aspect of the present invention, The synchronous adjustment of the patient's pulse pillow and the doctor's pulse pillow to the target height specifically includes: The control system independently controls the patient's pulse pillow airbag and the doctor's pulse pillow airbag, inflating or deflating them according to their respective target heights, ensuring that both pulse pillows reach the set heights simultaneously and maintain a coordinated state.
[0013] As a further aspect of the present invention, Maintaining the stability of the pulse pillow height for both doctor and patient to complete the pulse diagnosis procedure specifically includes: During pulse diagnosis, the stability maintenance module continuously monitors the airbag pressure and compensates for minor fluctuations in real time to keep the pulse pillow height and support posture constant. After the pulse diagnosis is completed, the airbag is depressurized and reset, specifically including: After the diagnosis and treatment are completed, the reset control module opens the airbag depressurization channel to slowly release the internal gas and restore the airbag pressure to the initial standby state; then the airway structure is locked and the pulse pillow returns to its initial shape.
[0014] A pressure-controlled dual-use pulse pillow system for both doctors and patients is available, capable of executing the aforementioned AI-based intelligent agent-based pressure-controlled dual-use pulse pillow application method.
[0015] As a further aspect of the present invention, it includes: Patient pulse pillow, doctor pulse pillow, pulse pillow connector, gas cylinder, and AI intelligent processor; The patient pulse pillow and the doctor pulse pillow are connected by a pulse pillow connector, which is configured as a telescopic length adjustment and / or universal angle adjustment structure. The patient pulse pillow has a pre-installed patient air cushion, and the doctor pulse pillow has a pre-installed doctor air cushion. The gas cylinder is connected to the patient's pre-placed air cushion and the doctor's pre-placed air cushion in a controllable on / off manner via valves; The AI intelligent processor is connected to the gas storage cylinder and its connecting valve via a circuit.
[0016] The present invention has the following beneficial effects: 1. Achieve a dual-use structure for both doctors and patients: Breaking away from the traditional single-mode pulse pillow designed solely for patient use, this design integrates the pulse pillows used by doctors and patients. By adjusting the arm postures of both doctors and patients, it not only enhances the comfort of doctors but also simultaneously adjusts the comfort of patients, thereby effectively improving overall stability and accuracy.
[0017] 2. Significantly reduces physician fatigue: By providing stable support for the doctor's forearm and incorporating an adjustable connector structure, it reduces the doctor's wrist suspension and forward tilting posture, effectively reducing shoulder, neck and wrist fatigue, and has significant ergonomic advantages.
[0018] 3. Improve the accuracy of pulse diagnosis: By automatically adjusting the height of the pulse pillow using artificial intelligence, the patient's wrist is in a natural and relaxed state when taking the pulse, avoiding the force and pulse distortion caused by improper height, thereby improving the accuracy of diagnosis.
[0019] 4. High level of intelligence: Introducing artificial intelligence technology into traditional Chinese medicine assistive devices can achieve automated adjustment based on individual differences between doctors and patients, reduce reliance on human experience, and improve standardization.
[0020] 5. Highly adaptable and widely applicable: It is applicable to various scenarios such as TCM outpatient clinics and home visits, and has good promotional value and practicality. Attached Figure Description
[0021] To more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the accompanying drawings used in the description of the embodiments or the prior art will be briefly introduced below. The structures, proportions, sizes, etc., drawn in this specification are only used to complement the content disclosed in the specification, so that those skilled in the art can understand and read them. Any modifications to the structure, changes in the proportional relationships, or adjustments to the size, without affecting the effects and objectives that the present invention can produce, should still fall within the scope of the technical content disclosed in the present invention.
[0022] Figure 1 This is a schematic diagram of the overall process of the application method of the AI-based controllable pressure pulse pillow for both doctors and patients provided in an embodiment of the present invention.
[0023] Figure 2 This is a schematic diagram illustrating the architectural principle of the AI-based controllable pressure pulse pillow system for both medical and patient use, provided in an embodiment of the present invention.
[0024] The attached diagram lists the components represented by each number as follows: Patient pulse pillow 1; Patient pre-placed air cushion 11; Doctor's pulse pillow 2; Doctor's pre-installed air cushion 21; 3. Pulse pillow connector; 4. Gas storage bottle; 5. AI intelligent processor. Detailed Implementation
[0025] The following specific embodiments illustrate the implementation of the present invention. Those skilled in the art can easily understand other advantages and effects of the present invention from the content disclosed in this specification. Obviously, the described embodiments are only some, not all, of the embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0026] The terms "upper," "lower," "left," "right," and "middle" used in this specification are merely for clarity of description and are not intended to limit the scope of the invention. Any changes or adjustments to their relative relationships, without substantially altering the technical content, should also be considered within the scope of the invention.
[0027] like Figure 1As shown, this invention provides a method for using a pulse pillow with controllable pressure control based on an AI agent, suitable for both doctors and patients. This method effectively addresses the shortcomings of traditional pulse pillows, such as doctor fatigue and insufficient pulse diagnosis accuracy, achieving a synergistic effect of dual use for both doctors and patients and precise diagnosis. Specifically, it includes the following steps: S1: Collect body parameters and treatment posture parameters of both doctor and patient; The specific process is as follows: The system obtains several body and posture data such as the doctor's height, weight, arm length, and common sitting posture through the input terminal, while also obtaining data such as the patient's height, wrist circumference, and natural forearm posture. After data collection is completed, it is transmitted to the AI intelligent processor. The AI intelligent processor standardizes the data, removes outliers and unifies the data format, providing an accurate input basis for subsequent calculations. This allows for a comprehensive understanding of individual characteristics of doctors and patients, ensuring a high degree of matching and adherence to actual needs in the subsequent process. S2: Based on the collected parameters, the optimal height data of the pulse pillow for doctors and patients is calculated using artificial intelligence algorithms; The specific process is as follows: The processed patient parameters and doctor parameters are simultaneously input into a preset collaborative calculation model. Based on ergonomic rules and pulse diagnosis operation standards, the model generates pulse pillow height matching values for the patient and the doctor respectively. Through a collaborative optimization algorithm, it outputs the optimal height combination for both sides, such as the required support height difference at the bottom of the arm when the doctor's fingers contact the patient's wrist, ensuring that both parties are in a comfortable posture during the same pulse diagnosis process. This collaborative approach breaks through the limitations of traditional single control and achieves simultaneous satisfaction of the needs of both doctors and patients. S3: Convert altitude data into barometric pressure control data; The specific process is as follows: Corresponding to the patient's pulse pillow and the doctor's pulse pillow, airbags are pre-installed inside. The system has a pre-stored model of the correspondence between the height of the pulse pillow and the airbag pressure. Based on the AI intelligent processor, the target height value is mapped to the corresponding inflation or deflation volume, and a continuous air pressure control command sequence is generated. The command sequence includes, but is not limited to, inflation rate, inflation duration, and air pressure threshold parameters, to ensure the accurate execution of subsequent airway control. Currently, during the pulse diagnosis process, especially when doctors support their arms on the pulse pillow for a long time, the upper arm and elbow are prone to exerting force or being compressed by the weight of the upper body, resulting in excessive local pressure on the pulse pillow. At this time, a single air bladder will produce a state of excessive local compression and excessive local bulging, which can easily lead to the wrist being excessively stretched, thus affecting the stability and accuracy of pulse diagnosis. Therefore, as a preferred embodiment, the pre-installed airbags of the doctor's pulse pillow and / or the patient's pulse pillow are set as partitioned airbags. The partitioned airbags include at least one elbow part airbag and at least one wrist part airbag. The at least one elbow part airbag and the at least one wrist part airbag each have an internal pressure monitoring component and a corresponding target air pressure. The at least one elbow part airbag and the at least one wrist part airbag are inflated independently to more clearly define the support independence of the wrist and elbow, reduce the disturbance correlation caused by the pressure change of one part to the other part, make the overall coordination stronger, and effectively improve the stability and accuracy of pulse diagnosis. More preferably, when the internal pressure monitoring components of at least one elbow airbag and at least one wrist airbag are used for a long time, performance degradation may occur. Therefore, a mechanical collaborative verification architecture is further established. The mechanical collaborative verification architecture is set as a first axis corresponding to the upper side of the wrist airbag, a second axis corresponding to the upper side of the elbow airbag, and a telescopic ruler that is respectively transferred between the first axis and the second axis, so as to mechanically measure the distance between the two axes in real time through the telescopic ruler. In application, the target value range of the telescopic ruler set on the specific doctor's pulse pillow is first determined based on the corresponding target air pressure and height of the elbow and wrist air bladders. Then, under normal use, the accuracy of the support height of the wrist and elbow is checked by determining whether the telescopic ruler is within the target value range. It can also detect and adjust the internal pressure monitoring component in a timely manner from the outside when the performance deteriorates.
[0028] More preferably, the visual monitoring component can be pre-set to correspond to the telescopic ruler, and the visual monitoring component and the AI intelligent processor are connected by a circuit to realize automated monitoring of mechanical changes. S4: Controls the gas cylinder to inflate or deflate the air bag based on the gas pressure control data. The specific process is as follows: After receiving the command, the gas path control module opens the gas supply channel of the gas storage cylinder and controls the inflation flow and total supply of the internal pre-set airbags of the patient's pulse pillow and the doctor's pulse pillow according to the command parameters. At the same time, during the control process, the air pressure signals inside the two sets of airbags are collected in real time. The real-time air pressure inside the two sets of airbags is compared with the corresponding air pressure threshold and closed-loop correction is performed to prevent the height deviation caused by excessive or insufficient air pressure. S5: Synchronously adjust the patient's pulse pillow and the doctor's pulse pillow to the target height; The specific process is as follows: The control system independently controls the patient's pulse pillow airbag and the doctor's pulse pillow airbag, inflating or deflating them according to their respective target heights. This ensures that both pulse pillows reach the set heights simultaneously and maintain a coordinated state, eliminating the need for both parties to actively adjust their postures. This enhances the level of intelligence and improves overall operational efficiency through synchronous control. S6: Maintain the stability of the pulse pillow for both doctor and patient to complete the pulse diagnosis procedure; The specific process is as follows: During the pulse diagnosis process, the stability maintenance module continuously monitors the air pressure of the airbag and makes real-time compensation and adjustment for minor fluctuations to keep the height of the pulse pillow and the support posture constant. This avoids the patient's wrist from exerting force due to unstable support, ensuring that the pulse is in a natural state, and thus directly improving the reliability of the pulse diagnosis results. S7: After pulse diagnosis, control the airbag to depressurize and reset; The specific process is as follows: After the diagnosis and treatment are completed, the reset control module opens the airbag depressurization channel to slowly release the internal gas and restore the airbag pressure to the initial standby state; then the airway structure is locked, the pulse pillow returns to its initial shape, and it is ready for the next use. The reset process simplifies the operation steps and extends the service life of the equipment. When using a continuous outpatient scenario, the control method can be designed to be upgraded to a rapid switching mode. The system saves commonly used doctor and patient parameter templates, which can be called with one click to complete high-level control, greatly shortening the preparation time. In an alternative, the height calculation model can use a deep learning model instead of a traditional rule model, and improve the height matching accuracy through training with a large amount of pulse diagnosis data, thus adapting to more people with special body types.
[0029] like Figure 2 As shown, this embodiment of the invention also provides a controllable support and pressure controllable pulse pillow system for both doctors and patients based on an AI intelligent agent, specifically including a patient pulse pillow 1, a doctor pulse pillow 2, a pulse pillow connector 3, a gas storage cylinder 4, and an AI intelligent processor 5; wherein, the patient pulse pillow 1 and the doctor pulse pillow 2 are connected by the pulse pillow connector 3, and the pulse pillow connector 3 is configured with a telescopic length adjustment and / or universal angle adjustment structure, so that both doctors and patients can obtain the best support state under different body shapes and postures.
[0030] The patient pulse pillow 1 has a built-in patient pre-installed air cushion 11, and the doctor pulse pillow 2 has a pre-installed doctor pre-installed air cushion 21. The gas storage cylinder 4 is connected to the patient pre-installed air cushion 11 and the doctor pre-installed air cushion 21 in a controllable on / off manner through valves. The AI intelligent processor 5 is connected to the gas storage cylinder 4 and its connecting valve through a circuit, so as to improve the overall inflation and deflation matching degree and user comfort by simultaneously incorporating the body parameters of the doctor and the patient into the high-level calculation model of the AI intelligent processor 5.
[0031] Although the present invention has been described in detail above with general descriptions and specific embodiments, modifications or improvements can be made to it, which will be obvious to those skilled in the art. Therefore, all such modifications or improvements made without departing from the spirit of the present invention fall within the scope of protection claimed by the present invention.
Claims
1. A method for using a pulse pillow with controllable support and pressure based on an AI intelligent agent, suitable for both medical staff and patients, characterized in that... Includes the following steps: Collect physical parameters and treatment posture parameters from both doctors and patients; Based on the collected parameters, the optimal height of the pulse pillow for both doctor and patient is calculated using artificial intelligence algorithms. Convert altitude data into barometric pressure control data; Based on the air pressure regulation data, control the gas cylinder to inflate or deflate the air bag; Simultaneously adjust the patient's pulse pillow and the doctor's pulse pillow to the target height; Maintaining the pulse pillows of both the doctor and patient at a high level of stability is essential for completing the pulse diagnosis procedure. After the pulse diagnosis, depressurize and reset the airbag.
2. The method for applying the AI-based, controllable pressure-support pulse pillow for both medical and patient use according to claim 1, characterized in that, The collection of physical parameters and treatment posture parameters from both the doctor and the patient specifically includes: The system obtains several body and posture data of doctors, including height, weight, arm length, and common sitting posture, through the input terminal. At the same time, it also obtains data of patients' height, wrist circumference, and natural forearm posture. After data collection is completed, it is transmitted to the AI intelligent processor. The AI intelligent processor standardizes the data, removes outliers and unifies the data format, providing an accurate input basis for subsequent calculations. This allows for a comprehensive understanding of individual characteristics of doctors and patients, ensuring a high degree of matching and adherence to actual needs in the subsequent process. The optimal height data for the doctor-patient pulse pillow is calculated using artificial intelligence algorithms based on the collected parameters, specifically including: The processed patient parameters and doctor parameters are synchronously input into a preset collaborative calculation model. Based on ergonomic rules and pulse diagnosis operation standards, the model generates the patient's pulse pillow height matching value and the doctor's pulse pillow height matching value respectively. The model outputs the optimal height combination for both sides of the doctor and patient through a collaborative optimization algorithm, such as the required support height difference at the bottom of the arm when the doctor's fingers contact the patient's wrist.
3. The method for applying the AI-based, controllable pressure-support pulse pillow for both medical and patient use according to claim 2, characterized in that, The conversion of altitude data into barometric pressure control data specifically includes: Corresponding to the patient's pulse pillow and the doctor's pulse pillow, each has a pre-installed airbag. The control system has a pre-stored model of the correspondence between the pulse pillow height and the airbag pressure. Based on the AI intelligent processor, the target height value is mapped to the corresponding inflation or deflation volume, generating a continuous air pressure control command sequence. The command sequence includes inflation rate, inflation duration, and air pressure threshold parameters to ensure accurate execution of subsequent airway control.
4. The method for applying the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both medical and patient use as described in claim 3, characterized in that, The conversion of altitude data into barometric pressure control data further includes: The pre-installed airbags of the doctor's pulse pillow and / or the patient's pulse pillow are set as partitioned airbags, which include at least one elbow portion airbag and at least one wrist portion airbag. At least one elbow portion airbag and at least one wrist portion airbag each have an internal pressure monitoring component and a corresponding target air pressure, and at least one elbow portion airbag and at least one wrist portion airbag are inflated independently.
5. The method for applying the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both medical and patient use according to claim 4, characterized in that, The conversion of altitude data into barometric pressure control data further includes: Establish a mechanical collaborative verification architecture; The mechanical collaborative verification architecture is configured as a first axis corresponding to the upper edge side of the wrist airbag, a second axis corresponding to the upper edge side of the elbow airbag, and a telescopic ruler that is respectively connected between the first axis and the second axis. The telescopic ruler is used to mechanically measure the distance between the two axes in real time. When applied, the target value range of the telescopic ruler set on the specific doctor's pulse pillow is first determined based on the corresponding target air pressure and height of the elbow and wrist air bladders. Then, under normal use, the accuracy of the support height of the wrist and elbow is checked by determining whether the telescopic ruler is within the target value range. It can also detect and adjust the internal pressure monitoring component in a timely manner from the outside when the performance deteriorates. The preset visual monitoring component corresponds to the telescopic ruler. The visual monitoring component is connected to the AI intelligent processor through a circuit, thereby automatically monitoring the mechanical changes.
6. The method for applying the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both medical and patient use according to claim 5, characterized in that, The operation of inflating or deflating the gas cylinder into the gas bag based on the gas pressure regulation data specifically includes: After receiving the command, the gas path control module opens the gas supply channel of the gas storage cylinder and controls the inflation flow and total supply of the pre-set airbags inside the patient's pulse pillow and the doctor's pulse pillow according to the command parameters. At the same time, during the control process, the air pressure signals inside the two sets of airbags are collected in real time. The real-time air pressure inside the two sets of airbags is compared with the corresponding air pressure threshold and closed-loop correction is performed to prevent the height deviation caused by excessive or insufficient air pressure.
7. The method for applying the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both medical and patient use as described in claim 6, characterized in that, The synchronous adjustment of the patient's pulse pillow and the doctor's pulse pillow to the target height specifically includes: The control system independently controls the patient's pulse pillow airbag and the doctor's pulse pillow airbag, inflating or deflating them according to their respective target heights, ensuring that both pulse pillows reach the set heights simultaneously and maintain a coordinated state.
8. The method for applying the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both medical and patient use according to claim 7, characterized in that, Maintaining the stability of the pulse pillow height for both doctor and patient to complete the pulse diagnosis procedure specifically includes: During pulse diagnosis, the stability maintenance module continuously monitors the airbag pressure and compensates for minor fluctuations in real time to keep the pulse pillow height and support posture constant. After the pulse diagnosis is completed, the airbag is depressurized and reset, specifically including: After the diagnosis and treatment are completed, the reset control module opens the airbag depressurization channel to slowly release the internal gas and restore the airbag pressure to the initial standby state; then the airway structure is locked and the pulse pillow returns to its initial shape.
9. A pulse pillow system with controllable support and pressure for both medical staff and patients, characterized in that, It is capable of performing the application method of the AI-based intelligent agent-controlled pressure-controllable pulse pillow for both doctors and patients as described in any one of claims 1-8.
10. The pressure-controllable dual-use pulse pillow system for both doctors and patients according to claim 9, characterized in that, include: Patient pulse pillow, doctor pulse pillow, pulse pillow connector, gas cylinder, and AI intelligent processor; The patient pulse pillow and the doctor pulse pillow are connected by a pulse pillow connector, which is configured as a telescopic length adjustment and / or universal angle adjustment structure. The patient pulse pillow has a pre-installed patient air cushion, and the doctor pulse pillow has a pre-installed doctor air cushion. The gas cylinder is connected to the patient's pre-placed air cushion and the doctor's pre-placed air cushion in a controllable on / off manner via valves; The AI intelligent processor is connected to the gas storage cylinder and its connecting valve via a circuit.