Portable ultrasonic apparatus and control method of portable ultrasonic apparatus

文档序号：1967842 发布日期：2021-12-17 浏览：23次中文

阅读说明：本技术 便携超声设备及便携超声设备的控制方法 (Portable ultrasonic apparatus and control method of portable ultrasonic apparatus ) 是由谢崇军胡锐刘福生谭泽伟雷晶晶张皖于 2020-06-17 设计创作，主要内容包括：本申请提供一种便携超声设备及便携超声设备的控制方法,包括处理器、电源组件和外壳,外壳包括旋转连接的第一外壳和第二外壳,第一外壳朝向第二外壳的面上设置有第一显示屏,用于显示超声检测操作界面和/或超声检测结果；第二外壳朝向第一外壳的面上设置有控制面板；外壳上设置有第二显示屏,第二显示屏与处理器连接并用于输出设备信息,第二显示屏在第一外壳和第二外壳贴合时至少部分露出于外壳。通过第二显示屏输出设备信息,使得用户可以在看便携超声设备的主显示屏不方便的情况下,通过输出元件方便快捷地了解到设备信息。(The application provides a portable ultrasonic device and a control method of the portable ultrasonic device, and the portable ultrasonic device comprises a processor, a power supply assembly and a shell, wherein the shell comprises a first shell and a second shell which are connected in a rotating mode, and a first display screen is arranged on the surface, facing the second shell, of the first shell and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell; the shell is provided with a second display screen, the second display screen is connected with the processor and used for outputting equipment information, and at least part of the second display screen is exposed out of the shell when the first shell and the second shell are attached. The device information is output through the second display screen, so that a user can conveniently and quickly know the device information through the output element under the condition that the user cannot conveniently see the main display screen of the portable ultrasonic device.)

1. A portable ultrasonic device is characterized by comprising a host and a flip, wherein the flip is connected with the host in a flip manner;

the host comprises a processor and a power supply assembly, and the power supply assembly supplies power to the processor; a control panel is arranged on the surface of the flip cover facing the host, and the control panel is connected with the processor and used for receiving the input of a user to the portable ultrasonic equipment; a first display screen is arranged on the surface of the host machine facing the flip cover, and the first display screen is connected with the processor and is used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result;

the host computer and/or be provided with the second display screen on the flip, the second display screen is in flip upset to with at least part exposes when the host computer laminating, the second display screen with the treater is connected, the second display screen is used for output device information.

2. The portable ultrasound device of claim 1, wherein:

the second display screen is positioned on the surface of the host computer, which faces away from the flip cover; or the like, or, alternatively,

the second display screen is positioned on the surface of the turnover cover, which is back to the host; or the like, or, alternatively,

the second display screen is positioned on the side surface of the host; or the like, or, alternatively,

the second display screen is positioned on the side surface of the flip; or the like, or, alternatively,

the host machine further comprises a handle, the handle is arranged on the side face of the host machine, and the second display screen is located on the handle; or the like, or, alternatively,

the size of the host is larger than that of the flip, when the host and the flip are attached, at least part of the surface of the host facing the flip is exposed out of the flip, and the second display screen is positioned at the part of the host exposed out of the flip; or the like, or, alternatively,

the size of the flip is larger than that of the host, when the host is attached to the flip, at least part of the surface of the flip facing the host is exposed out of the host, and the second display screen is located at the part of the flip exposed out of the host.

3. A portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly powering the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface, facing the second shell, of the first shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving the input of a user to the portable ultrasonic equipment;

the shell is provided with a second display screen, the power supply assembly supplies power to the second display screen, the second display screen is connected with the processor and used for outputting equipment information, and at least part of the second display screen is exposed out of the shell when the first shell and the second shell are attached.

4. The portable ultrasound device of claim 3, wherein:

the second display screen is positioned on the surface of the first shell, which faces away from the second shell; or the like, or, alternatively,

the second display screen is positioned on the side surface of the first shell; or the like, or, alternatively,

the second display screen is positioned on the side surface of the second shell; or the like, or, alternatively,

the shell further comprises a handle, the handle is arranged on the first shell and/or the side face of the second shell, and the second display screen is located on the handle; or the like, or, alternatively,

the size of the second shell is larger than that of the first shell, when the first shell is attached to the second shell, the surface, facing the first shell, of the second shell is at least partially exposed out of the first shell, and the second display screen is located on the portion, exposed out of the first shell, of the second shell.

5. The portable ultrasound device of claim 3, wherein the device information comprises: at least one of power supply information, power-on self-test information, communication information, state information and factory information.

6. The portable ultrasound device as recited in claim 5, wherein the power supply component comprises a battery, the power supply information comprising: at least one of a power supply mode, battery power, endurance time, charging efficiency, and a wireless charging state.

7. The portable ultrasound device according to claim 3, further comprising a first sensor disposed within the housing, the first sensor for generating a sensing signal when a trigger signal is sensed and communicated to the processor; the processor is further used for controlling the second display screen to convert the output equipment information into the low-power-consumption output equipment information or not to output the equipment information or controlling the second display screen to convert the low-power-consumption output equipment information or not to output the equipment information into the output equipment information when the sensing signal is received.

8. The portable ultrasound device, as recited in claim 7, wherein the first sensor comprises: at least one of a pressure sensor, a touch sensor, a gesture sensor, a sound sensor, an angle sensor, a distance sensor.

9. The portable ultrasound device according to claim 3, further comprising a second sensor disposed within the housing, the second sensor for generating a sensing signal when a trigger signal is sensed and communicated to the processor; and the processor is also used for controlling the second display screen to switch the content of the output equipment information or the direction of the equipment information when receiving the induction signal.

10. The portable ultrasound device according to claim 3, further comprising a distance sensor disposed within the housing, the distance sensor comprising a transmitting tube and a receiving tube, wherein a transmitting side of the transmitting tube and a receiving side of the receiving tube are covered with a light transmissive material, a gap is provided between the transmitting side of the transmitting tube and the receiving side of the receiving tube and the light transmissive material, and a light blocking material is disposed at a corresponding gap between the transmitting tube and the receiving tube.

11. The portable ultrasound device according to claim 3, further comprising an infrared sensor disposed within the housing and in communication with an exterior of the housing through an infrared-sensitive aperture, the infrared-sensitive aperture coated with an infrared-sensitive ink.

12. The portable ultrasound device according to any of claims 3 to 11, wherein the processor comprises a main processor for processing ultrasound test data and a microprocessor for acquiring device information and controlling the second display screen to output device information.

13. The portable ultrasound device according to claim 3, wherein the processor has stored therein word stock data for display on the second display screen.

14. The portable ultrasound device according to claim 5, wherein the power supply assembly comprises a wireless powered receiver for receiving wirelessly transmitted energy and providing power to the portable ultrasound device;

the power supply information comprises at least one of the state of the wireless power supply receiver, the efficiency of wireless power supply and the centering state of the wireless power supply receiver; and/or the presence of a gas in the gas,

the power supply assembly further comprises a battery, the wireless power supply receiver is further configured to receive wirelessly transmitted energy and charge the battery, and the power supply information comprises wireless charging efficiency.

15. The portable ultrasound device according to claim 3, wherein the second display screen comprises at least one of an LCD screen, an OLED screen, a non-backlit liquid crystal screen, an electronic ink screen, an STN screen.

16. The portable ultrasound device according to claim 15, wherein the second display screen is at least one of a liquid crystal screen without backlight, an electronic ink screen, an STN screen; the second display screen is used for outputting the equipment information and comprises: and at least one item of the liquid crystal screen without the backlight, the electronic ink screen and the STN screen continuously outputs equipment information.

17. A portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly powering the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell is provided with an output element, the power supply assembly supplies power to the output element, the output element is connected with the processor, at least part of the output element is exposed out of the shell when the first shell and the second shell are attached, and the output element is used for outputting equipment information.

18. The portable ultrasound device according to claim 17, wherein the output element comprises at least one of a display screen, a lamp, and a projection device.

19. The portable ultrasound device of claim 18, wherein:

the output element is positioned on the surface of the first shell, which faces away from the second shell; or the like, or, alternatively,

the output element is positioned on the surface of the second shell, which faces away from the first shell; or the like, or, alternatively,

the output element is positioned on the side surface of the first shell; or the like, or, alternatively,

the output element is located at a side of the second housing; or the like, or, alternatively,

the housing further comprises a handle disposed on the first housing and/or a side of the second housing, the output element being located on the handle; or the like, or, alternatively,

the size of the first shell is larger than that of the second shell, when the first shell and the second shell are attached, the surface of the first shell facing the second shell is at least partially exposed out of the second shell, and the output element is positioned at the part of the first shell exposed out of the second shell; or the like, or, alternatively,

the size of the second housing is larger than that of the first housing, when the first housing and the second housing are attached, the surface of the second housing facing the first housing is at least partially exposed out of the first housing, and the output element is located at the part of the second housing exposed out of the first housing.

20. A portable ultrasonic device is characterized by comprising a processor, a power supply assembly, a first display screen, a control panel and a shell, wherein the power supply assembly supplies power to the processor, the first display screen and the control panel;

the housing comprises a first housing and a second housing, the first housing and the second housing are rotatably connected, and the first housing and the second housing have a closed state and an open state; when the first shell is in an open state, the first display screen and the control panel are at least partially exposed between the first shell and the second shell, the first display screen is used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result, and the control panel is used for receiving input of a user for controlling the portable ultrasonic equipment;

the shell is provided with an output element, the power supply assembly supplies power to the output element, the output element is connected with the processor, and the output element is used for outputting equipment information.

21. The portable ultrasound device according to claim 20, wherein the output element comprises at least one of a display screen, a light, a projection device, an audio device, and a vibration device.

22. The portable ultrasound device of claim 20, wherein the power supply component comprises a battery, the device information comprising: at least one of power supply information, power-on self-test information, communication information, state information and factory information.

23. The portable ultrasound device according to claim 20, wherein the output element comprises at least one of a display screen, a lamp, and a projection device disposed on a face of the first housing facing the second housing or a face of the second housing facing the first housing.

24. A portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly powering the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface, facing the second shell, of the first shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving input of a user for controlling the portable ultrasonic equipment;

when the equipment is shut down or in standby and the first shell and the second shell form a preset angle, the first display screen displays equipment information.

25. A portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly powering the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface, facing the second shell, of the first shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving input of a user for controlling the portable ultrasonic equipment;

the surface of the first shell, which faces away from the second shell, is provided with a second display screen, the power supply assembly supplies power to the second display screen, and the second display screen is used for displaying an ultrasonic detection result.

26. A method of controlling a portable ultrasound device comprising a processor, a power supply assembly and a housing, the housing comprising a first housing and a second housing rotatably connected; a first display screen for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result is arranged on the surface of the first shell facing the second shell, and a control panel is arranged on the surface of the second shell facing the first shell; the shell is provided with an output element, and the output element is at least partially exposed out of the shell when the first shell and the second shell are attached, and the device is characterized by comprising:

a processor acquires equipment information of the portable ultrasonic equipment;

the processor transmits the equipment information to the output element for output;

when the equipment information meets a first preset condition, the processor controls the output element to output the equipment information in a low power consumption mode or not;

the equipment information comprises at least one of power supply information, power-on self-test information, communication information, state information and factory information.

27. The control method of claim 26, wherein the device information satisfying a first preset condition includes:

the state information is equipment shutdown, and the power supply information is battery power supply and lasts for a preset time; and/or the presence of a gas in the gas,

the state information is equipment shutdown, the power supply information is battery power supply, and the battery power is less than a preset value.

28. The control method according to claim 26, further comprising,

when the processor receives a first control signal, controlling the output element to output or not output the device information from the low power consumption to output the device information;

the first control signal includes:

a signal input by a user; or the like, or, alternatively,

a sensing signal generated by triggering of the first sensor; or the like, or, alternatively,

the equipment is switched from shutdown to a state information change signal of equipment startup; or the like, or, alternatively,

the battery power supply is converted into a power supply information change signal of the external power supply.

29. The control method of claim 28, wherein the sensing signal generated by the first sensor trigger comprises:

the touch control device comprises at least one of a sensing signal generated by pressing a preset area, a sensing signal generated by touching the preset area, a sensing signal generated by executing a preset gesture above the preset area, a sensing signal generated by receiving a preset sound and a sensing signal generated by changing an included angle of a first shell relative to a second shell.

30. The control method according to claim 26, further comprising:

when the equipment information meets a second preset condition, the processor controls the output element to continuously output the equipment information;

the device information meeting a second preset condition includes:

the state information is equipment standby; or the like, or, alternatively,

the state information is that the equipment is started and the first shell and the second shell form a preset angle; or the like, or, alternatively,

the power supply information supplies power to an external power supply, and the state information is equipment shutdown.

31. The control method according to any one of claims 26 to 30, wherein the processor includes a main processor and a microprocessor;

the processor obtaining device information of the portable ultrasound device comprises:

the microprocessor acquires equipment information of the portable ultrasonic equipment; or the main processor acquires the equipment information of the portable ultrasonic equipment and transmits the equipment information to the microprocessor;

the processor transmits the equipment information to the output element for output; when the device information meets a first preset condition, the processor controlling the output element to output the device information with low power consumption or not comprises the following steps:

the microprocessor transmits the equipment information to the output element for output; and when the equipment information meets a first preset condition, the microprocessor controls the output element to output the equipment information in a low power consumption mode or not.

Technical Field

The application relates to the technical field of medical equipment, in particular to portable ultrasonic equipment and a control method of the portable ultrasonic equipment.

Background

In order to bring convenience to home visit, a plurality of ultrasonic diagnosis devices are designed to be portable and easy to carry.

When a user needs to carry a portable ultrasonic device for a doctor, in order to know whether a certain portable ultrasonic device meets the requirement of the doctor, the user needs to start the portable ultrasonic device to acquire related information, so that the portable ultrasonic device is troublesome to operate, long in waiting time, extremely inconvenient to use and not suitable for emergency doctor conditions.

Disclosure of Invention

In this summary, concepts in a simplified form are introduced that are further described in the detailed description. This summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

In a first aspect, the present application provides a portable ultrasound device, comprising a main unit and a flip, wherein the flip is connected to the main unit in a flip manner;

In a second aspect, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly powering the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

In a third aspect, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

In a fourth aspect, the present application provides a portable ultrasound device, comprising a processor, a power supply assembly, a first display screen, a control panel, and a housing, wherein the power supply assembly supplies power to the processor, the first display screen, and the control panel, the processor is connected to the first display screen, the processor is connected to the control panel, the processor is disposed inside the housing, the power supply assembly is at least partially disposed inside the housing, and the first display screen and the control panel are disposed on the housing;

In a fifth aspect, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface, facing the second shell, of the first shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving input of a user for controlling the portable ultrasonic equipment;

when the equipment is shut down or in standby and the first shell and the second shell form a preset angle, the first display screen displays equipment information.

In a sixth aspect, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing;

the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface, facing the second shell, of the first shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving input of a user for controlling the portable ultrasonic equipment;

In a seventh aspect, the present application provides a control method of a portable ultrasound apparatus including a processor, a power supply assembly, and a housing including a first housing and a second housing rotatably connected; a first display screen for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result is arranged on the surface of the first shell facing the second shell, and a control panel is arranged on the surface of the second shell facing the first shell; the shell is provided with an output element, and the output element is at least partially exposed out of the shell when the first shell and the second shell are attached, and the device is characterized by comprising:

a processor acquires equipment information of the portable ultrasonic equipment;

the processor transmits the equipment information to the output element for output;

when the equipment information meets a first preset condition, the processor controls the output element to output the equipment information in a low power consumption mode or not;

the equipment information comprises at least one of power supply information, power-on self-test information, communication information, state information and factory information.

In the embodiment of the application, the output element is added on the portable ultrasonic equipment, so that a doctor can conveniently and quickly know the equipment information through the output element under the condition that the main display screen of the portable ultrasonic equipment is inconvenient to see.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive labor.

FIG. 1 shows a schematic diagram of a portable ultrasound device of an embodiment of the present application;

FIG. 2 shows a schematic diagram of a portable ultrasound device of an embodiment of the present application;

FIG. 3 shows a schematic diagram of a portable ultrasound device of an embodiment of the present application;

FIG. 4 shows a schematic diagram of a portable ultrasound device of an embodiment of the present application;

FIG. 5 shows a schematic view of a portable ultrasound device of an embodiment of the present application;

FIG. 6 shows a schematic diagram of a portable ultrasound device of an embodiment of the present application;

fig. 7 shows a flowchart of a control method of a portable ultrasound device according to an embodiment of the present application.

Detailed Description

Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings.

In one embodiment, as shown in fig. 1, the present application provides a portable ultrasound device comprising a main unit 1 and a flip 2, wherein the flip 2 is connected to the main unit 1 in a reversible manner, the main unit 1 comprises a processor and a power supply assembly, and the power supply assembly supplies power to the processor. The surface of the flip cover 2 facing the main machine 1 is provided with a control panel 4, and the control panel 4 is connected with the processor and used for receiving the input of the user to the portable ultrasonic device. The main machine 1 is provided with a first display screen 3 on the surface facing the flip cover 2, and the first display screen 3 is connected with the processor and is used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result. The host and/or the flip cover are/is provided with a second display screen (not shown in the figure), at least part of the second display screen is exposed when the flip cover 2 is turned over to be attached to the host 1, the second display screen is connected with the processor, and the second display screen is used for outputting equipment information. When the flip cover 2 is attached to the host 1, at least part of the second display screen is exposed, so that a user can acquire device information without opening the flip cover 2. When the portable ultrasonic equipment is turned off, the user needs to turn on the portable ultrasonic equipment to obtain the equipment information in the past, the operation is very complicated, the waiting time is long, the user can directly check the equipment information through the second display screen, extra turn-on operation can be omitted, and great convenience is particularly provided for the condition that the user needs to carry the portable ultrasonic equipment for emergency treatment.

In one embodiment, the second display screen may be located at any position that can be visually observed by the user when the flip 2 is attached to the main body 1, including but not limited to at least one of the following: the side of the host computer, the side of the flip cover or the side of the flip cover. In one embodiment, the main body 1 may further include a handle 5, the handle 5 is disposed on a side surface of the main body, and the second display screen may also be disposed on the handle. In one embodiment, the size of the host 1 and the size of the flip 2 may be different, the size of the host 1 may be larger than the size of the flip 2, when the host 1 and the flip 2 are attached, at least a part of the surface of the host 1 facing the flip 2 is exposed out of the flip, and the second display screen is located at a part of the host 1 exposed out of the flip 2; the size of the flip 2 may also be larger than that of the host 1, when the host 1 and the flip 2 are attached, at least a portion of the flip 2 facing the host 1 is exposed to the host 1, and the second display screen is located at a portion of the flip 2 exposed to the host 1.

In one embodiment, as shown in fig. 2, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing 10, the power supply assembly providing power to the processor, the processor being disposed inside the housing 10, the power supply assembly being at least partially disposed inside the housing 10; the shell 10 comprises a first shell 11 and a second shell 12, the first shell 11 and the second shell 12 are rotatably connected, the first shell 11 and the second shell 12 can be rotated to be attached, a first display screen 13 is arranged on the surface of the first shell 11 facing the second shell 12, and the first display screen 13 is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel 14 is provided on the side of the second housing 12 facing the first housing 11, the control panel 14 being connected to the processor for receiving user input to the portable ultrasound device. The housing 10 is provided with a second display screen (not shown), the power supply assembly supplies power to the second display screen, the second display screen is connected with the processor, at least part of the second display screen is exposed out of the housing 10 when the first housing and the second housing are attached, and the second display screen is used for outputting device information. When the user needs to know the equipment information, the user can directly and conveniently know the equipment information from the second display screen without starting the equipment, so that the operation steps of the user are simplified, and the operation time is shortened.

In one embodiment, the Processor may be at least one of an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a Central Processing Unit (CPU), a controller, a microcontroller, and a microprocessor.

In one embodiment, the second display screen may include at least one of an LCD screen, an OLED screen, a non-backlit liquid crystal screen, an electronic ink screen, and an STN screen, without limitation to the type of the second display screen.

In one embodiment, the portable ultrasound device further comprises a probe, a transmitting circuit, a transmitting/receiving selection switch, a receiving circuit and a beam forming circuit, wherein the transmitting circuit can excite the probe to transmit ultrasonic waves to target tissues; the receiving circuit can receive the ultrasonic echo returned from the target tissue through the probe so as to obtain an ultrasonic echo signal/data; the ultrasonic echo signals/data are sent to a processor after being processed by the beam forming circuit. The processor processes the ultrasound echo signals/data to obtain an ultrasound image of the target tissue. The ultrasound image obtained by the processor may be stored in memory or may be displayed on the first display 13.

In one embodiment, the portable ultrasound device may be similar to a laptop computer, with the processing elements mostly arranged in a second housing, such that the thickness of the second housing is larger than the thickness of the first housing, and during use, the first housing may be rotated to expose the first display 13 and the control panel 14 out of the housings; the processing elements inside the portable ultrasound device may also be evenly arranged within the first and second housings such that the thicknesses of the first and second housings are approximately equal; in other cases, the processing elements inside the portable ultrasound device may also be mostly arranged in the first housing, such that the thickness of the first housing is larger than the thickness of the second housing, and during use, the second housing may be rotated to a suitable angle, such that the first display 13 and the control panel 14 are exposed from the housings.

In one embodiment, the control panel 14 has at least one of a plurality of keys, knobs, trackballs, and touch pads for receiving input operations from a user pressing a key, rotating a knob or a trackball, or touching a touch pad, and converting the corresponding operations into electrical signals to be transmitted to the processor. In other embodiments, the control panel 14 may also be a touch screen for receiving a touch operation of a user on the touch screen.

In one embodiment, the device information includes, but is not limited to: at least one of power supply information, power-on self-test information, communication information, state information and factory information.

Wherein the power information includes but is not limited to: power supply related parameters such as current of the power supply, voltage of the power supply, stability of the power supply and the like. The power supply component may include a battery, in embodiments where the power supply component includes a battery, the portable ultrasound device may be powered by the battery or an external power source, and the power information may include, but is not limited to: at least one of a power supply mode, battery power, endurance time, charging efficiency, and a wireless charging state. The power supply mode comprises the power supply mode which is adopted by the portable ultrasonic equipment in battery power supply or external power supply; the battery power includes a specific value of the battery power, and can also be a percentage of the remaining battery power in the total battery power; the endurance time comprises at least one of endurance time in a shutdown state, endurance time in a standby state and endurance time in a startup state; the charging efficiency includes an efficiency in which the external power supply charges the battery when the external power supply is turned on.

The external power supply of the portable ultrasound device may include not only power supply through an external power line, but also a wireless power supply mode, and the power supply mode in the power supply information may further include which power supply mode of the device in external power line power supply, wireless power supply or battery power supply. The power supply assembly of the portable ultrasound device may include a wireless power receiver for receiving the wirelessly transmitted energy and providing power to the portable ultrasound device, and the power supply information may further include at least one of a status of the wireless power receiver, an efficiency of the wireless power supply, and a centering status of the wireless power receiver. In embodiments where the power supply component includes a battery, the wireless power receiver is further configured to receive wirelessly transmitted energy and charge the battery, and the power supply information may further include an efficiency of the wireless charging.

The status information in the device information includes the status of the portable ultrasound device, including but not limited to at least one of: starting up, shutting down or standby the equipment; the first shell and the second shell are opened or attached; the first housing and the second housing are angled; a control state of the device, such as a Demo state or a normal use state, etc.

The power-on self-test information in the device information includes information obtained by the portable ultrasonic device in the power-on self-test process, for example: whether the equipment operates normally, abnormal information if the equipment is abnormal, and latest updating time of the equipment system. The communication information in the device information includes information communicated between the portable ultrasound devices, such as: a department at a time needs the equipment, etc. The factory information in the device information includes relevant parameter information configured when the portable ultrasonic device is shipped, for example: the serial number of the equipment when the equipment is delivered, the signals of the components used by the equipment, the delivery parameters, the trademark, the model and the like of the system.

In one embodiment, the second display screen may display the device information in various visual manners such as characters, symbols, images, colors, and the like. The second display screen may also display conventional information, e.g. the second display screen may also display time information, etc.

In one embodiment, the second display screen is not limited to one, and the portable ultrasound device may have a plurality of second display screens, which may be located at the same location or at different locations.

As shown in fig. 3-6, in one embodiment, the second display screen may be located at any user-perceivable location on the portable ultrasound device when the first housing 11 and the second housing 12 are mated, including but not limited to: at least one of on a face of the first housing facing away from the second housing, on a side of the first housing, and on a side of the second housing. When the side face of the first housing is the first housing and the second housing, except for the face where the first housing and the second housing are attached to each other and the face where the first housing faces away from the second housing, the side face of the second housing is the face where the second housing faces away from the first housing and the face where the second housing faces away from the first housing when the first housing and the second housing are attached to each other.

Illustratively, as shown in fig. 3, in one embodiment, the second display screen 16 may be located on a face of the first housing 11 facing away from the second housing 12. The second display screen 16 may be located on a side of the face close to the rotational joint of the first housing 11 and the second housing 12, or may be located on a side of the face away from the rotational joint of the first housing 11 and the second housing 12. The shape of the second display screen 16 is not limited, and may be various shapes such as a rectangle, a square, a circle, etc., and the size of the second display screen 16 is also not limited, and may be as large as the surface of the first housing 11 departing from the second housing 12, or smaller than the size of the surface of the first housing 11 departing from the second housing 12.

Illustratively, as shown in fig. 4, in one embodiment, the second display screen 16 may be located at a side of the first housing 11. As shown, the first housing 11 has four sides around the face where the first housing 11 and the second housing 12 are attached, and the second display screen 16 may be located on either side.

In one embodiment, the housing 10 further comprises a handle 15, the handle 15 being disposed at a side of at least one of the first housing 11 and the second housing 12, the handle 15 being for a user to hold to more comfortably carry the portable ultrasound device. The second display screen 16 may be located on the handle 15, and specifically, the second display screen 16 may be located on a side of the handle 15 facing the first housing 11, a side of the handle facing the second housing 12, or a side of the handle, which may be visually viewed by a user.

Illustratively, as shown in fig. 5, the housing 10 further includes a handle 15, the handle 15 is disposed on a side of the second housing 12 away from the rotational connection between the first housing 11 and the second housing 12, and the second display 16 is disposed on an outer side of the handle.

In one embodiment, the size of the second housing 12 is larger than that of the first housing 11, when the first housing 11 and the second housing 12 are attached, the surface of the second housing 12 facing the first housing 11 is at least partially exposed from the first housing 11, and the second display screen is located at the portion of the second housing 12 exposed from the first housing 11. The first housing and the second housing have different sizes, and when the first housing and the second housing are attached to each other, the second housing is at least partially exposed and positioned at a position visually perceivable by a user, and the second display screen 16 may be positioned at the position, so that the user can visually acquire device information from the second display screen.

Illustratively, as shown in fig. 6, the dimension of the second housing 12 in the direction perpendicular to the rotation joint is larger than the dimension of the first housing 11 in the direction perpendicular to the rotation joint, when the first housing 11 and the second housing 12 are attached, one end of the second housing 12 away from the rotation joint is exposed out of the first housing 11, and the second display screen is located at the part of the second housing 12 exposed out of the first housing 11. Of course, the second housing 12 may have a larger size than the first housing 11 in other directions, so that the second housing 12 is exposed to the first housing 11 at a different portion, and the second display screen 16 may be located at a different position. Further, the second display 16 may cover the entire exposed portion of the second housing 12, or may cover only a portion of the exposed portion of the second housing 12.

Without being limited to the above-described position, the second display screen may also be located at other positions of the portable ultrasound device as long as the position may be partially exposed when the first housing and the second housing are attached, so that the user can visually acquire device information from the second display screen.

In one embodiment, the portable ultrasound device further comprises a first sensor disposed in the housing 10, the first sensor being configured to generate a sensing signal when sensing the trigger signal and transmit the sensing signal to the processor; the processor is further configured to control the second display screen 16 to switch from outputting the device information to outputting the device information with low power consumption or not outputting the device information, or control the second display screen 16 to switch from outputting the device information with low power consumption or not outputting the device information to outputting the device information when receiving the sensing signal. The first sensor includes: at least one of a pressure sensor, a touch sensor, a gesture sensor, a sound sensor, an angle sensor, a distance sensor. Correspondingly, the trigger signal sensed by the first sensor comprises a pressure signal, a touch signal, a gesture signal, a sound signal, an angle signal or an object distance signal. Wherein the pressure signal comprises a specific pressure value and/or pressure change received by the sensor; the touch signal comprises that the sensor receives a touch operation which is not specific to a user or a specific touch operation; the gesture signal comprises that the sensor receives a specific or unspecific gesture performed by the user above the sensor; the sound signal comprises specific or unspecific sound received by the sensor, or a specific language; the angle signal comprises the change of an included angle between the first shell and the second shell received by the sensor, or the included angle between the first shell and the second shell reaches a preset value; the object distance signal comprises that the object distance sensor received by the sensor reaches a preset value or the distance of the object distance sensor changes.

In one embodiment, when the first sensor senses a corresponding trigger signal, the first sensor generates a sensing signal and transmits the sensing signal to the processor, and the processor is further configured to control the second display screen to switch between outputting device information and outputting device information with low power consumption or not outputting device information when receiving the sensing signal. For example, the processor controls the second display screen to convert the output device information into low power consumption output or non-output device information when receiving the pressure signal, and controls the second display screen to convert the low power consumption output or non-output device information into the output device information when receiving the touch signal. For another example, when the processor receives the gesture signal, the processor controls the second display screen to convert the output device information into low power consumption output or non-output device information, and when the processor receives the gesture signal again, the processor controls the second display screen to convert the low power consumption output or non-output device information into the output device information. When the processor receives the induction signal, the processor controls the second display screen to switch between the output equipment information and the low-power-consumption output or non-output equipment information, and can control the second display screen to output the low-power-consumption output or non-output equipment information to reduce the power consumption when the ultrasonic equipment supplies power to the battery and the battery power needs to be saved; when the external power supply supplies power, or the output power consumption of the second display screen is negligible relative to the power consumption of the equipment, the second display screen is controlled to output equipment information in a normal state, and the effect of ensuring the endurance time of the equipment is achieved.

In one embodiment, the portable ultrasound device further comprises a second sensor disposed in the housing, the second sensor being configured to generate a sensing signal when sensing the trigger signal and transmit the sensing signal to the processor; the processor is further used for controlling the second display screen to switch the content of the output equipment information or the direction of the equipment information when the induction signal is received. The second sensor includes at least one of various sensors such as a touch sensor, a press sensor, a gesture sensor, an angle sensor, or a sound sensor, and the sensing signal includes a corresponding touch signal, a press signal, a gesture signal, an angle signal, or a sound signal. The second sensor may be the same sensor as the first sensor described above, or may be a different sensor, and the sensing signal may be a specific sensing signal or may be unspecified sensing information.

In one embodiment, taking the second sensor as a touch sensor as an example, when the touch second sensor senses a touch operation of sliding from one side of the second display screen to the other side, the second display screen displays a screen switching effect of switching from the current screen to the next screen, and at the same time, the device information displayed on the current screen is switched to the device information displayed on the next screen. When the second display screen needs to display more equipment information, the equipment information cannot be displayed on the second display screen at the same time, so that the second display screen can initially display part of the equipment information, and a user can switch the equipment information displayed on the second display screen through the sensing element to acquire part of the equipment information which is not displayed under the initial condition. The initially displayed device information may be set by a user, or the most commonly used device information may be displayed by the system preset.

In one embodiment, taking the second sensor as an angle sensor as an example, when the second sensor senses that the included angle between the first housing and the second housing is increased from zero to a preset angle, the second sensor generates a sensing signal and transmits the sensing signal to the processor, and the processor controls the second display screen to rotate the display direction of the device information by 180 degrees. When the second display screen is located the one side of first shell dorsad second shell, when the user opened the first shell and the second shell of laminating each other to preset the angle, the second display screen changed for user's angle, rotated 180 degrees with the display direction of equipment information and was convenient for the user to look over the second display screen under the condition of opening first shell and second shell.

In one embodiment, the portable ultrasound device further comprises a distance sensor, the distance sensor is arranged on the shell and comprises a transmitting tube and a receiving tube, light-transmitting materials are covered on the transmitting side of the transmitting tube and the receiving side of the receiving tube, gaps are formed between the transmitting side of the transmitting tube and the receiving side of the receiving tube and the light-transmitting materials, and light-shielding materials are arranged in the gaps corresponding to the transmitting tube and the receiving tube. The setting of shading material makes the signal of launching tube transmission can not directly get into the receiver tube through the one side transmission that the printing opacity material is close to launching tube and receiver tube to cause the interference, also do not influence the signal of launching tube transmission simultaneously and meet target object transmission back signal entering receiver tube, the setting of shading material has reduced distance sensor's end and has made an uproar, has optimized distance sensor's response effect.

In one embodiment, the portable ultrasonic device is provided with an infrared sensor, the infrared sensor is arranged in the first shell and/or the second shell and is communicated with the outside of the first shell and/or the second shell through an infrared photosensitive hole, the infrared sensor senses a signal of an external shielding object through the infrared photosensitive hole, and the infrared photosensitive hole can be coated with infrared photosensitive ink. The infrared sensitive hole formed in the shell is visible in appearance due to the arrangement of the infrared sensor, so that the attractiveness of the portable ultrasonic equipment is affected, the sensitive hole can be filled by coating infrared sensitive ink, the attractive appearance effect is achieved, and the function of the infrared sensor is not affected.

In one embodiment, the processor is further configured to obtain the power information and the status information, where the processor may be composed of a plurality of sub-processors, and the power information and the status information may be obtained by the processor as a whole or by some of the sub-processors in the processor. The processor also controls the output unit to output the equipment information, wherein the output unit can be controlled by the processor as a whole to output the equipment information, or the output unit can be controlled by partial sub-processors to output the equipment information, the sub-processors controlling the output unit to output the equipment information can be the same processor as the sub-processors acquiring the power supply and the state information, or can be partial same processors or different processors, wherein the acquired information can be transmitted between two or more processors, and the control signals can also be transmitted between two or more processing devices.

In one embodiment, the processor comprises a main processor and a microprocessor, wherein the main processor is used for processing ultrasonic detection data, such as processing an ultrasonic echo signal received by an ultrasonic probe to obtain an ultrasonic image map; and the microprocessor is used for acquiring the power supply information and the state information and controlling the second display screen to output the equipment information. Similar to the processor discussed above, the main processor and the microprocessor may be regarded as two sub-processors forming the whole processor, and the microprocessor may obtain the power supply information, the state information and other device information directly from the related elements of the portable ultrasound device, or from the main processor; accordingly, the main processor may retrieve device information from the associated components of the portable ultrasound device and transmit the device information to the microprocessor. In other embodiments, the processor may be integral and used to process the ultrasound test data and also to obtain device information and control the output of the second display screen.

In one embodiment, the microprocessor may have stored therein font data for display on said second display screen. The word stock data used for displaying on the second display screen is stored in the microprocessor, so that the word stock data stored in the microprocessor can be directly read by the second display screen when the information of the equipment is output, and the display speed and the switching speed of the second display screen are quicker.

In one embodiment, the second display screen is at least one of a liquid crystal display screen without backlight, an electronic ink screen and an STN screen, and the second display screen can continuously output the equipment information. Because the power consumption of the liquid crystal screen, the electronic ink screen and the STN screen without backlight is very low, the power consumption of the second display screen is kept in an output state continuously and is very low, and the second display screen can be ignored for the portable ultrasonic equipment, so that the equipment information can be continuously output without being switched to a low-power output or non-output state, and a user can conveniently check the equipment information without extra operation.

In one embodiment, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing; the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface of the first shell facing the second shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving the input of a user to the portable ultrasonic equipment; the shell is provided with an output element, the power supply assembly supplies power to the output element, the output element is connected with the processor, at least part of the output element is exposed out of the shell when the first shell and the second shell are attached, and the output element is used for outputting equipment information.

In one embodiment, the output element may be a visually perceptible output element including, but not limited to, at least one of a display screen, a lamp, and a projection device. When the output element is a display screen, the display screen can display the device information in various visual modes such as characters, symbols, images, colors and the like. When the output element is a projection device, the image projected by the projection device can display device information in various visual manners such as characters, symbols, images, colors, and the like. When the output element is a lamp, the number of the lamps can be one or more, and the device information can be displayed in various visual modes such as different colors, flickering, light intensity, different brightness combinations and the like of the lamps.

In one embodiment, the output element may be located anywhere where the user can visualize the sensory device information through the output element, including but not limited to at least one of the following: the output element is positioned on the surface of the first shell, which faces away from the second shell, the output element is positioned on the surface of the second shell, which faces away from the first shell, the output element is positioned on the side surface of the first shell, and the output element is positioned on the side surface of the second shell. In one embodiment, the housing further comprises a handle, which is arranged on the first housing and/or on a side of the second housing, the output element being located on the handle. In one embodiment, the size of the first housing is larger than that of the second housing, when the first housing and the second housing are attached, the surface of the first housing facing the second housing is at least partially exposed out of the second housing, and the output element is positioned at the part of the first housing exposed out of the second housing; or the size of the second shell is larger than that of the first shell, when the first shell and the second shell are attached, the surface of the second shell facing the first shell is at least partially exposed out of the first shell, and the output element is positioned at the part of the second shell exposed out of the first shell.

In one embodiment, the present application provides a portable ultrasound device comprising a processor, a power supply assembly, a display, a control panel, and a housing, the power supply assembly supplying power to the processor, the first display, and the control panel, the processor being connected to the first display, the processor being connected to the control panel, the processor being disposed inside the housing, the power supply assembly being disposed at least partially inside the housing, the first display and the control panel being disposed on the housing; the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell have a closed state and an open state; when the first shell is in the open position, the first display screen and the control panel are at least partially exposed between the first shell and the second shell, the first display screen is used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result, and the control panel is used for receiving input of a user for controlling the portable ultrasonic equipment; the shell is provided with an output element, the power supply assembly supplies power to the output element, the output element is connected with the processor, and the output element is used for outputting equipment information.

The closed state of the first housing and the second housing may be a state in which the first housing and the second housing are rotated to be attached, and the open state of the first housing and the second housing may be a state in which the first housing and the second housing are rotatably connected and the other portions are separated.

In one embodiment, the first display screen may be disposed on a face of the first housing facing the second housing, and the control panel may be disposed on a face of the second housing facing the first housing. In one embodiment, the first display screen and the control panel may both be disposed on a face of the first housing and the second housing. In other embodiments, the first display screen may be integrated with the control panel, and the first display screen may be a touch screen, which both receives the input from the user and displays the ultrasonic detection operation interface and/or the ultrasonic detection result.

In one embodiment, the output element comprises at least one of a display screen, a lamp, a projection device, an audio device, and a vibration device. Wherein display screen, lamp or projection equipment can be through visual ground mode display device information, and audio equipment can output device information through voice broadcast's mode, and vibration equipment can output device information through the vibration through the corresponding relation of vibration and device information, for example, when vibration equipment output portable ultrasonic equipment electric quantity, vibration equipment vibrates to represent the electric quantity twenty percent, vibrates two times to represent the electric quantity forty percent, and so on. When the output element is a display screen, a lamp or a projection device, the output element is at least partially exposed when the first housing and the second housing are in the open state for visual viewing by a user. When the output element is an audio device or a vibration device, the output element may be located inside the housing of the portable ultrasound device, or outside the housing, and may be located at any position where a user can sense sound or vibration.

In one embodiment, the power supply component includes a battery, and the device information includes: at least one of power supply information, power-on self-test information, communication information, state information and factory information.

In an embodiment, the output element comprises at least one of a display screen, a lamp and a projection device, which may be arranged on a face of the first housing facing the second housing and/or on a face of the second housing facing the first housing. The processor may be configured to control at least one of the display screen, the lamp, and the projection device to output the device information when the first housing and the second housing are in an open state, and to control at least one of the display screen, the lamp, and the projection device to output the device information with low power consumption or not when the first housing and the second housing are in a closed state.

In one embodiment, the processor is used for acquiring state information in the device information, the processor controls the output element to output or stop outputting the device information according to the acquired state information, and when the state information is that the first shell and the second shell are in the open state, the processor controls the output element to output the device information; when the state information is that the first shell and the second shell are in the closed state, the processor controls the output element to stop outputting the equipment information. When the output element includes at least one of a display screen, a lamp, and a projection device, the output element may be disposed on opposite faces of the first housing and the second housing, and when the first housing and the second housing are in a closed state, the output element is located between the first housing and the second housing, and is invisible from the outside, so that the appearance of the portable ultrasound device is more concise. No matter what kind of state the portable ultrasonic equipment is in on, off or standby at this moment, when the user wants to check the equipment information, the first shell and the second shell can be opened to expose the output element, and the processor controls the output element to output the equipment information for the user to check; when the user does not need to view the device information, the first housing and the second housing may be closed to place the output element in a non-visible state, and the processor controls the output element to stop outputting the device information.

In one embodiment, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing; the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface of the first shell facing the second shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving the input of a user for controlling the portable ultrasonic equipment; when the device is turned off or in standby and the first shell and the second shell form a preset angle, the first display screen is also used for displaying device information.

In the above embodiment, the first display screen may be configured to display an ultrasonic detection operation interface and/or an ultrasonic detection result when the device is turned on; the first display screen can be used for displaying equipment information when the equipment is turned off and the first shell and the second shell form a preset angle, and/or when the equipment is in standby and the first shell and the second shell form a preset angle. The preset angle is an angle at which the user can view the first display screen from between the first housing and the second housing, for example, the preset angle is an angle equal to or greater than 60 degrees. According to the portable ultrasonic equipment of the embodiment, when the equipment is in a power-off or standby state, a user does not need to power on the equipment, and equipment information can be directly checked through the first display screen, so that the user can check the information more conveniently and efficiently.

In one embodiment, the present application provides a portable ultrasound device comprising a processor, a power supply assembly and a housing, the power supply assembly supplying power to the processor, the processor being disposed within the housing, the power supply assembly being at least partially disposed within the housing; the shell comprises a first shell and a second shell, the first shell and the second shell are rotatably connected, and the first shell and the second shell can be rotated to be attached; a first display screen is arranged on the surface of the first shell facing the second shell, and the first display screen is connected with the processor and used for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result; a control panel is arranged on the surface of the second shell facing the first shell, and the control panel is connected with the processor and used for receiving the input of a user for controlling the portable ultrasonic equipment; the surface of the first shell, which faces away from the second shell, is provided with a second display screen, the power supply assembly supplies power to the second display screen, and the second display screen is used for displaying an ultrasonic detection result.

In the above embodiment, the ultrasonic detection operation interface and/or the ultrasonic detection result may be displayed through the first display screen for the medical staff to view; the ultrasonic detection result can be displayed through the second display screen for the testee to view. The display of the first display screen and the second display screen can be synchronous or asynchronous, and the displayed ultrasonic detection results can be the same or different, for example, the ultrasonic image map of the ultrasonic detection results displayed by the first display screen can display the measurement items and the evaluation results marked by the medical personnel, and the ultrasonic detection results on the second display screen can only display the ultrasonic image map and the evaluation results. The ultrasonic detection operation interface and/or the ultrasonic detection result are displayed through the first display screen, and the ultrasonic detection result is displayed through the second display screen, so that the testee can know the progress and the condition of ultrasonic detection, and the medical personnel and the testee can communicate conveniently.

For brevity of description, the same features in the embodiments are not repeated, but it is emphasized that the features in the embodiments can be arbitrarily combined within the feasible range, and due to the limitation of space, the features which are not mentioned in one embodiment can be reasonably supplemented with the features in other embodiments, and the related discussion of the same features in the embodiments can be reused in the embodiments. For example, the discussion of the related embodiments in which the portable ultrasound device includes the second display screen may be equally applicable to embodiments in which the portable ultrasound device includes an output element.

In one embodiment, the present application provides a method of controlling a portable ultrasound device, the ultrasound portable device comprising a processor, a power supply assembly, and a housing, the housing comprising a first housing and a second housing rotatably coupled; a first display screen for displaying an ultrasonic detection operation interface and/or an ultrasonic detection result is arranged on the surface of the first shell facing the second shell, and a control panel is arranged on the surface of the second shell facing the first shell; the shell is provided with an output element, and the output element is at least partially exposed out of the shell when the first shell and the second shell are attached, and the control method of the portable ultrasonic equipment comprises the following steps:

step 21, the processor acquires the device information of the portable ultrasonic device.

The processor obtains device information of the portable ultrasonic device, wherein the device information may include at least one of power supply information, power-on self-test information, communication information, status information and factory information.

Step 22, the processor transmits the device information to the output element for output.

The output element may include, but is not limited to, at least one of a display screen, a light, a projection device, an audio device, and a vibration device. The processor transmits the device information to the output element, the output element outputs the device information, and the output element can output the device information in a user-perceivable manner through different vision, different sound or different vibration.

And step 23, when the device information meets the first preset condition, controlling the output element to output the device information in a low power consumption mode or not by the processor.

The device information may include power information and status information, and the first preset condition may include: the state information is equipment shutdown, and the power supply information is power supplied to a battery and lasts for a preset time; and/or the state information is that the equipment is shut down, the power supply information supplies power to the battery, and the electric quantity of the battery is less than a preset value. Through the setting of the first preset condition, under the condition that the battery is powered and the electric quantity of the battery needs to be saved, the processor controls the output element to output low power or not output equipment information, so that the power consumption of the output element is reduced, and the endurance time of the portable ultrasonic equipment is prolonged.

In one embodiment, when the processor receives the first control signal, the output element is controlled to convert from low power consumption output or non-output device information to output device information; wherein the first control signal includes, but is not limited to, at least one of: the device comprises a signal input by a user, an induction signal generated by triggering of a first sensor, a state information change signal for converting the device into the device to be started when the device is turned off, and a power supply information change signal for converting the battery power supply into the external power supply. The signals input by the user comprise signals input by the user through a control panel or signals input by any other input equipment to the ultrasonic portable equipment; the first sensor is triggered by the sensing signal, wherein the first sensor may also include a triggering operation of the user sensed by a sensor provided on the portable ultrasonic device, and the type of the sensor is not limited herein. When the processor receives the first control signal, the fact that the user intends to check the equipment information to perform corresponding operation is explained, or the user wants to check the equipment information in the corresponding operation process, and the power supply mode is converted from battery power supply to external power supply so that the power consumption of the output element does not need to be considered.

In one embodiment, the sensing signal generated by the first sensor trigger comprises: the touch control device comprises at least one of a sensing signal generated by pressing a preset area, a sensing signal generated by touching the preset area, a sensing signal generated by executing a preset gesture above the preset area, a sensing signal generated by receiving a preset sound and a sensing signal generated by changing an included angle of a first shell relative to a second shell.

In one embodiment, the method further comprises the steps that when the equipment information meets a second preset condition, the processor controls the output element to continuously output the equipment information; the second preset condition includes, but is not limited to, at least one of the following: the state information is the equipment startup or the equipment standby, the state information is the equipment startup, the first shell and the second shell form a preset angle, the power supply information supplies power for the external power supply, and the state information is the equipment shutdown. When the portable ultrasonic equipment is started or in a standby state, the main power consumption is on the processor, and the power consumption of the output equipment can be ignored, so that the output element can be controlled to continuously output the equipment information even if the battery is powered, and the problem of power consumption is not considered. When the power supply information supplies power to the external power supply and the state information is off, the external power supply supplies power without considering the power consumption of the battery, and the output element can continuously output the equipment information, so that a user can check the equipment information at any time without starting. Wherein the output element continuously outputting the device information includes the output element continuously outputting the device information for a period of time until the corresponding device information changes.

In one embodiment, a processor includes a main processor and a microprocessor; step 21, the processor acquiring the device information of the portable ultrasonic device comprises: the microprocessor acquires equipment information of the portable ultrasonic equipment; and/or the main processor acquires the equipment information of the portable ultrasonic equipment and transmits the equipment information to the microprocessor. Step 22, the processor transmits the device information to the output element for outputting, and step 23, when the device information meets a first preset condition, the processor controls the output element to output the device information with low power consumption or not to output the device information, wherein the step comprises the following steps: the microprocessor transmits the equipment information to the output element for output; when the device information meets the first preset condition, the microprocessor controls the output element to output the device information with low power consumption or not.

In one embodiment, the processor comprises a main processor and a microprocessor, wherein the main processor is used for processing ultrasonic detection data, such as processing an ultrasonic echo signal received by the ultrasonic probe to obtain an ultrasonic image map; and the microprocessor is used for acquiring the power supply information and the state information and controlling the second display screen to output the equipment information. In one case, the microprocessor may obtain device information directly from the corresponding components of the portable ultrasound device, such as battery level information directly from the battery; in another case, the host processor obtains the device information and transmits the device information to the microprocessor, including the microprocessor reading the device information obtained by the host processor when needed. Further, the microprocessor may transmit the device information to an output element, which outputs the device information. When the device information meets the first preset condition, the microprocessor controls the output element to output the device information with low power consumption or not.

In one embodiment, the microprocessor may be a low power microprocessor, such as an MCU or low power processing chip, so that when information needs to be output via the output element, the main processor does not need to be activated, thereby reducing power consumption. When the device information meets the second preset condition, the microprocessor controls the output element to continuously output the device information, and no matter what state the main processor is in, the microprocessor can be continuously in the working state to control the output element to continuously output the device information, so that a user can check the device information at any time. When the output element outputs or does not output the equipment information with low power consumption, the microprocessor can be in a standby state all the time, and the standby state of the microprocessor can be regarded as a low-power-consumption working state, so that when the microprocessor receives a first control signal, the microprocessor can quickly enter the working state to control the output element to output the equipment information, a user can acquire the information more conveniently, and meanwhile, the power consumption is lower. Because the microprocessor has low power consumption, the microprocessor can be always in a working state to receive the first control signal at any time and control the output element to convert the low power consumption output or non-output into the output equipment information. When the output element outputs or does not output the equipment information with low power consumption, the microprocessor can be in a closed state, and when the microprocessor receives the first control signal, the microprocessor is quickly started to acquire the equipment information and controls the output element to output the equipment information. The power consumption of the microprocessor is very low in a standby or working state, and a long-time endurance use scene of the portable ultrasonic equipment can be supported; furthermore, the microprocessor is in a power-off state and is started again when receiving the first control signal, so that the power consumption can be further reduced, and the requirement on the endurance time of the portable ultrasonic equipment is met.

In an embodiment, the processor may also be a single processor, and when the processor is in a standby state or a power-off state and the output element needs to output the device information, the processor may be turned on to obtain the device information and control the output element to output the device information, and then the processor may enter the standby state or the power-off state again to reduce power consumption.

In one embodiment, the processor transmits the device information to the output element for output, and the processor can control the output element to continuously output the device information, and also can control the output element to switch from the output device information to low-power-consumption output or not to output the device information. In one embodiment, the processor may control the output element to continuously output the device information with low power consumption. In one embodiment, the processor may further control the output element to enter low power consumption output or no output of the device information from the output device information, and may wake up the output element again to output the device information, for example, may wake up the output element according to a change in the device information or according to a user trigger.

In one embodiment, the processor controls the output element to continuously output the device information when the device information meets the second preset condition. Wherein the second preset condition may include, but is not limited to, at least one of the following: the state information is equipment standby; the state information is that the equipment is started and the first shell and the second shell form a preset angle; the power information supplies power to the external power supply, and the state information is the shutdown of the device.

The second preset condition may include that the state information is that the device is powered on and the first shell and the second shell form a preset angle; the preset angle includes the condition that the first housing is attached to the second housing, or the angle formed by the first housing and the second housing is small, so that a user cannot easily acquire device information from the first display screen, for example, the preset angle is an angle smaller than or equal to 30 degrees. When the state information is the equipment start, although the first display screen is opened to display the equipment information, the first shell and the second shell form a first preset angle, so that a user can check the equipment information through the first display screen inconveniently, the processor controls the output element to output the equipment information, and the user can check the equipment information through the output element more conveniently.

The second preset condition may further include that the status information is device standby, and no matter the portable ultrasound device is in a battery-powered or external power supply state, when the device is in standby, the main power consumption of the portable ultrasound device is concentrated on the processor, and the power consumption of the output element is small and relatively negligible, so that the output element can be controlled by the processor to output the device information.

The second preset condition may further include that the power information supplies power to the external power source and the status information is that the device is powered off. When the power information is used for supplying power to the battery, the power consumption of the portable ultrasonic device needs to be reduced so as to reduce the power consumption of the battery, wherein the mode of reducing the power consumption comprises that an output element outputs the device information with low power consumption or does not output the device information; and when the power supply information supplies power for the external power supply, the power consumption of the portable ultrasonic equipment can not be considered, and meanwhile, because the equipment is powered off, a user cannot directly acquire the equipment information through the first display screen, so that when the power supply information supplies power for the external power supply and the state information is the equipment power off, the processor can control the output element to output the equipment information.

And when the power supply information and the state information accord with at least one of the second preset conditions, the processor controls the output element to output the equipment information. The processor may control the second display to continue displaying the device information until the power information and/or the status information changes to no longer meet the second predetermined condition.

In one embodiment, when the power supply information and the state information acquired by the processor meet a third preset condition, the processor controls the output element to output the equipment information. The third preset condition of the power information and the state information comprises that the power information supplies power to the battery and the state information is shutdown of the equipment, when the battery supplies power and the equipment is shut down, the user cannot obtain the equipment information from the first display screen, and at the moment, the output element outputs the equipment information to enable the user to conveniently and quickly obtain the relevant information.

In one embodiment, the output element outputs the device information when the portable ultrasound device is powered off and the battery is powered, and since the battery has a limited power, the power consumption needs to be reduced to improve the endurance time, and therefore, the processor needs to output or not output the device information with low power consumption when the output element is controlled to meet the first preset condition. The output element outputs the device information in a low power consumption mode, for example, the output element is used as a display screen, and the output element outputs the device information in a low power consumption mode, for example, the output element outputs the device information in a low power consumption mode, such as a mode that the output element displays without backlight, a mode that the output element displays with weak brightness, and a flicker mode.

The first preset condition includes, but is not limited to, at least one of that the output element outputs the device information for a preset time and the power supply information is battery power less than a preset value when the device is powered off and the battery is powered on. The length of the preset time is the default set time length in the system, and can also be adjusted and set by a user. The preset value of the battery power may also be a preset value or a value set by the user himself. When the output element outputs the device information for the preset time, the user can be considered to know the device information within the preset time, and after the requirement of the user for the device information is met, the portable ultrasonic device can output the device information in a low power consumption mode or stop outputting the device information, so that the power consumption is reduced. When the battery power is less than the preset value, if the output element continues to output the device information in a normal state, the portable ultrasonic device may not have sufficient power to start up and the like, so when the battery power is less than the preset value, the processor may control the output element to output with low power consumption or not to output to save the battery power, and in this case, the user may also know the device information of the portable ultrasonic device with lower battery power without additional start-up operation when seeing the output element to output with low power consumption or not outputting the device information.

In one embodiment, when the portable ultrasound device enters a low power output or does not output device information, the portable ultrasound device may be further woken up from the low power output or not output to output the device information. The processor may be further configured to control the output element to convert from low power consumption output or no output device information to output device information when the first control signal is received. Wherein the output device information may be that the output element outputs the device information in a conventional manner with a conventional power consumption. The first control signal may be a control signal input by a user to the portable ultrasonic device through various input modes, may also be a sensing signal generated by triggering of a sensor, and may also be a signal triggered by a change of device information of the portable ultrasonic device detected by a processor.

Specifically, the first control signal may include, but is not limited to, at least one of the following:

the first control signal may include a state information change signal for switching from the device power-off to the device power-on. When the portable ultrasonic device is switched from the power-off state to the power-on state, the main power consumption is concentrated on the processor, and the power consumption of the output element is relatively negligible, so that the device information does not need to be output or output at low power consumption to control the energy consumption. Meanwhile, in the process of starting up the device, the user often needs to pay attention to the device information, so that when the processor receives a first control signal for converting the device from shutdown to startup, the processor controls the output element to output the device information from low power consumption or not to output the device information.

The first control information may further include a power information change signal for converting the battery power into the external power. When the portable ultrasonic device is converted from battery power supply to external power supply, the problem of power consumption of the battery does not need to be considered, so that the processor can control the output element to output device information from low power consumption or not to output the device information. Meanwhile, when the user connects the portable ultrasonic device to the external power supply, the external power supply charges the battery, and the output element is activated to output the device information, so that the user can conveniently check the charging state of the battery.

The first control signal may include a signal of a user input received through the control panel. The first control signal can be a signal input by any user, and when the user needs to check the equipment information, the user can randomly dial input elements such as keys or knobs on the control panel to wake up the output elements; the first control signal may also be a specific input signal, for example, a user needs to dial a specific key on the control panel to wake up the output element. The first control signal may also include a control signal input by a user in other ways than through the control panel.

The first control signal may also include a sensed signal generated by a first sensor trigger, e.g., a user triggering the sensor to generate the first control signal and transmit it to the processor.

In one embodiment, the portable ultrasound device may comprise a contact and/or contactless sensor that is triggered when a user presses, touches and/or performs a predetermined gesture over a predetermined area, and the first control signal comprises a trigger signal of the contact and/or contactless sensor. The touch sensor includes a sensor activated by user contact, including a push sensor (including a button), a touch sensor, and the like, and the non-contact sensor includes a sensor triggered by a signal inducing non-contact, including an infrared sensor, and the like.

The first sensor may further include, according to a sensing object classification of the sensor: at least one of a pressure sensor, a touch sensor, a gesture sensor, a sound sensor, an angle sensor, a distance sensor. When the sensor is a pressing type sensor, a user presses a preset area to trigger first control information; when the sensor is a touch sensor, the user touches the designated area to trigger the first control information. The touch sensor can sense a preset pressure value to trigger a first control signal, and can also sense pressure to trigger the first control signal, and similarly, the touch sensor can sense a preset touch action to trigger a first signal, and can sense a touch action to trigger a first signal. When the sensor is a gesture sensor, a user triggers a first control signal when executing a preset gesture over a preset area, the preset gesture can be any gesture, the gesture sensor triggers the first control signal as long as a shield is sensed over the sensor, or the preset gesture can also be a specific gesture, and the infrared sensor triggers first control information only when sensing the movement of the specific gesture over the sensor.

The first sensor may include a sound sensor that is triggered when a predetermined sound command is input by a user, and the first control signal includes a trigger signal of the sound sensor. The sound sensor may be a voice recognition device, and when a user speaks a predetermined language, the sound sensor is triggered to generate a first control signal, and the controller controls the output element to convert from low power consumption output or non-output device information to output device information. The sound sensor may also be other sound sensors, and the predetermined sound instruction may be a non-specific sound instruction or a specific sound instruction, and is not limited to sensing speech sound, and may also be used for sensing other types of sound, for example, the sound sensor is used for sensing a tapping sound, and when the sound sensor senses the sound of tapping the housing, a trigger signal is generated.

The first sensor may comprise an angle sensor for sensing an angle between the first housing and the second housing. The angle sensor can respond to the change of the included angle between the first shell and the second shell, the change of the included angle can be changed into the increase of the included angle and also can be changed into the decrease of the included angle, and the included angle can also be changed into the original angle after a series of changes. When the user changes the included angle between the first housing and the second housing, the user actually operates the portable ultrasonic device, which indicates that the user is to further use the portable ultrasonic device or place the portable ultrasonic device, and the user often needs to know the device information at this time, so that the state information change signal of the change of the included angle between the first housing and the second housing serves as the first control signal to wake up the output element. The angle sensor can also sense an included angle between the first shell and the second shell to reach a preset angle, for example, when the output device is a display screen, the preset angle of the included angle between the first shell and the second shell is an angle which is convenient for a user to check the display screen.

The first sensor may further comprise a distance sensor, and the first sensor is triggered to generate a sensing signal when a target object is in a distance with the distance sensor, wherein the target object may be a table top, a hand of a user, or the like.

The first control signal may be at least one of the first control signals described above, and the processor is configured to control the output element to convert from low power consumption output or non-output device information to output device information when the at least one first control signal is received. Of course, the first control signal is not limited to the above listed but may be other signals that facilitate user activation of the output element.

It should be emphasized that the description of the device in the embodiment of the portable ultrasound device may also correspond to the embodiment of the control method applied to the output element of the portable ultrasound device, and will not be described herein again.

The present invention has been described in terms of specific examples, which are provided to aid understanding of the invention and are not intended to be limiting. For a person skilled in the art to which the invention pertains, several simple deductions, modifications or substitutions may be made according to the idea of the invention.

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