A power supply device interface interaction method and system
By displaying operation graphics and parameter values on the power supply device interface and playing guiding animations, the problem of complex and unintuitive operation is solved, realizing simple and intuitive interface operation and improving ease of use and efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- GUANGZHOU ZHIYUAN INSTR CO LTD
- Filing Date
- 2025-02-10
- Publication Date
- 2026-06-19
AI Technical Summary
The parameter settings of existing power supply equipment operation interfaces are complex and unintuitive, lacking guidance, resulting in low ease of use.
By acquiring the selected test mode, the system displays operation graphics and parameter values on the display interface based on adjustable parameters, plays guiding animations, and adjusts the display status and parameter values in response to operation commands. Dynamic animations are used to transform parameters into intuitive visual images and clarify operation steps.
The operation process has been simplified, making the interface more intuitive and improving the ease of use and operational efficiency of the device.
Smart Images

Figure CN120161982B_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of electrical digital data processing technology, and in particular to a power supply device interface interaction method and system. Background Technology
[0002] Power supply equipment is a device that converts other forms of energy into electrical energy and provides a stable current to circuits and devices. It is a core component of electronic devices and systems, ensuring the proper functioning of most electronic devices and systems. The user interface of a power supply is the intuitive window through which users interact with the device. Through this interface, users can control various functions of the power supply and obtain relevant status information to meet different application needs. At the same time, the user interface is also an important way for users to understand the operating status of the power supply and to diagnose faults. Therefore, the user-friendliness and ease of use of the interface are crucial considerations when designing power supply equipment.
[0003] In related technologies, the operation interface of power supply equipment usually presents parameters in the form of text, numbers, forms or static graphics. When setting parameters in the operation interface of power supply equipment in this way, the operation is complicated and not intuitive, the efficiency is low, and there is a lack of intuitive guidance, resulting in low ease of use of the equipment. Summary of the Invention
[0004] This application provides a power supply device interface interaction method and system, which solves the problems in the prior art where setting parameters in the power supply device operation interface is complicated and not intuitive, inefficient, and lacks intuitive guidance, resulting in low device usability. It can make the interface operation simpler and more intuitive, and improve the usability and operation efficiency of the device.
[0005] Firstly, this application provides a power supply device interface interaction method, including:
[0006] Obtain the selected test mode, which includes multiple different adjustable parameters of the power supply device;
[0007] Based on each of the adjustable parameters, the corresponding operation graphics and parameter values are displayed on the display interface, and the guide animation corresponding to the test mode is played. The guide animation is a dynamic screen showing the adjustment method of each of the adjustable parameters and the change of the display state of the corresponding operation graphics.
[0008] When the guiding animation ends, in response to the operation command on the operation graphic, the display state of the corresponding operation graphic in the display interface and the parameter value of the corresponding adjustable parameter are adjusted based on the operation command, wherein different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0009] Optionally, the step of displaying corresponding operation graphics and parameter values on the display interface based on each of the adjustable parameters includes:
[0010] Query the pre-stored display information corresponding to each of the adjustable parameters. The pre-stored display information includes the operation graphic corresponding to the adjustable parameter, the display position of the operation graphic, the parameter value, and the display position of the parameter value.
[0011] The operation graphic and the parameter value are displayed on the display interface according to the display position of the operation graphic and the display position of the parameter value.
[0012] Optionally, playing the guide animation corresponding to the test mode includes:
[0013] Obtain the pre-stored guidance process of the test mode, the pre-stored guidance process including the guidance sequence and guidance actions of each of the operation graphics;
[0014] Based on the guided actions, each of the operation graphics is operated sequentially according to the guided order to realize the playback of the guided animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guided actions.
[0015] Optionally, playing the guide animation corresponding to the test mode includes:
[0016] Obtain the guidance operation information of the operation graphics corresponding to each of the adjustable parameters, and operate the operation graphics corresponding to each of the adjustable parameters in a random order based on the guidance operation information to realize the playback of the guidance animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guidance operation information.
[0017] Optionally, if the introductory animation has finished playing, the following may also be included:
[0018] Enable the touch screen operation function of the display interface or display operation gesture icons on the display interface to make the operation graphics operable.
[0019] Optionally, the operation instructions include the operation direction and the operation distance, and adjusting the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface based on the operation instructions includes:
[0020] When the operation attribute of the operation graphic is a sliding attribute, the display state of the operation graphic and the adjustment direction of the parameter value of the associated adjustable parameter are determined according to the operation direction, and the adjustment intensity of the display state of the operation graphic and the adjustment value of the associated adjustable parameter are determined according to the operation distance.
[0021] According to the adjustment direction, the adjustment intensity, and the adjustment value, the display state of the operation graphic and the parameter values of the associated adjustable parameters are simultaneously adjusted on the display interface.
[0022] Optionally, the operation instruction includes the number of clicks, and adjusting the display state of the corresponding operation graphic in the display interface and the parameter value of the corresponding adjustable parameter based on the operation instruction includes:
[0023] When the operation attribute of the operation graphic is a click attribute, the preset adjustment lookup table corresponding to the operation graphic is queried according to the number of clicks to obtain the display state to be switched of the operation graphic and the value of the associated adjustable parameter to be switched.
[0024] Adjust the display state of the operation graphic to the state to be switched, and adjust the parameter values of the adjustable parameters associated with the operation graphic to the parameter values to be switched.
[0025] Secondly, this application also provides a power supply device interface interaction device, including:
[0026] An acquisition module is used to acquire a selected test mode, which includes multiple different adjustable parameters of the power supply device;
[0027] The display module is used to display the corresponding operation graphics and parameter values on the display interface based on each of the adjustable parameters;
[0028] The playback module is used to play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment method of each of the adjustable parameters and the change of the display state of the corresponding operation graphics.
[0029] An adjustment module is used to, in response to an operation command on the operation graphic after the guide animation has finished playing, adjust the display state of the corresponding operation graphic in the display interface and the parameter value of the corresponding adjustable parameter based on the operation command, wherein different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0030] Thirdly, this application also provides a power supply device interface interaction device, the device comprising:
[0031] One or more processors;
[0032] Storage device for storing one or more programs.
[0033] When the one or more programs are executed by the one or more processors, the one or more processors implement the power device interface interaction method described in this application.
[0034] Fourthly, this application also provides a storage medium for storing computer-executable instructions, which, when executed by a computer processor, are used to perform the power device interface interaction method described in this application.
[0035] In this application, after selecting a test mode, corresponding operation graphics and parameter values are displayed on the display interface based on each adjustable parameter, and a guide animation corresponding to the test mode is played. Upon completion of the guide animation, in response to operation commands on the operation graphics, the display state of the corresponding operation graphics and the parameter values of the corresponding adjustable parameters on the display interface are adjusted based on the operation commands. By transforming parameters into intuitive visual objects through dynamic animation and clarifying operation steps using guide animation, this solves the problems of complex and unintuitive operation, low efficiency, and low usability of setting parameters in the operation interface of power supply devices in existing technologies. It makes interface operation simpler and more intuitive, improving the usability and operational efficiency of the device. Attached Figure Description
[0036] Figure 1 A flowchart illustrating a power supply device interface interaction method provided in an embodiment of this application;
[0037] Figure 2 A flowchart illustrating a power device interface interaction method that includes displaying operation graphics and parameter values, provided in an embodiment of this application;
[0038] Figure 3 A schematic diagram of a display interface in photovoltaic mode provided in an embodiment of this application;
[0039] Figure 4 A flowchart illustrating a power device interface interaction method including a playback guide animation, provided as an embodiment of this application;
[0040] Figure 5 A flowchart illustrating a power device interface interaction method that includes adjusting display status and parameter values, provided as an embodiment of this application;
[0041] Figure 6 A flowchart of another power device interface interaction method including adjusting display status and parameter values provided in an embodiment of this application;
[0042] Figure 7 A module structure block diagram of a power supply device interface interaction device provided in an embodiment of this application;
[0043] Figure 8 This is a schematic diagram of the structure of a power supply device interface interaction device provided in an embodiment of this application. Detailed Implementation
[0044] The embodiments of this application will be further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the embodiments of this application and are not intended to limit the scope of the embodiments. Furthermore, it should be noted that, for ease of description, only the parts relevant to the embodiments of this application are shown in the accompanying drawings, not the entire structure.
[0045] The terms "first," "second," etc., used in the specification and claims of this application are used to distinguish similar objects and not to describe a specific order or sequence. It should be understood that such use of data can be interchanged where appropriate so that embodiments of this application can be implemented in orders other than those illustrated or described herein, and the objects distinguished by "first," "second," etc., are generally of the same class and the number of objects is not limited; for example, a first object can be one or more. Furthermore, in the specification and claims, "and or or" indicates at least one of the connected objects, and the character "or" generally indicates that the preceding and following related objects have an "or" relationship.
[0046] This application provides a power supply device interface interaction method that can be applied to parameter setting scenarios for the operation interfaces of AC high-voltage power transmission equipment, low-voltage power distribution equipment, DC power distribution equipment, AC or DC charging equipment, AC or DC power supplies and load equipment, etc. The aforementioned business scenarios are merely exemplary and illustrative; in practical applications, they can also be applied to any other power supply device requiring parameter settings. In this application's power supply device interface interaction method, the executing entity for each step can be a computer device. This computer device refers to any electronic device with data computing, processing, and storage capabilities, such as mobile phones, PCs (Personal Computers), tablet computers, and other terminal devices, or it can be a server or other similar device. This application does not limit the scope of the method.
[0047] Figure 1 A flowchart illustrating a power supply device interface interaction method provided in this application embodiment is shown below. Figure 1 As shown, it specifically includes:
[0048] Step S101: Obtain the selected test mode, wherein the test mode includes multiple different adjustable parameters of the power supply device.
[0049] The test mode is used to characterize different parameter setting modes in the power supply device's operating interface, such as basic mode, photovoltaic mode, and battery mode. This test mode includes multiple adjustable parameters of the power supply device. Adjustable parameters can be relevant parameters of the power supply device that can be adjusted within the test mode. For example, in basic mode, the multiple adjustable parameters of the power supply device are voltage, current, power, and resistance. These adjustable parameters can be used to display corresponding operation graphics and parameter values on the display interface.
[0050] Step S102: Based on each adjustable parameter, display the corresponding operation graphics and parameter values on the display interface, and play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment method of each adjustable parameter and the change of the display state of the corresponding operation graphics.
[0051] The display interface refers to the interface in the power supply equipment used to display key parameters, status indicators, and other relevant information. The operation graphic can be a visual graphic used to adjust the values of adjustable parameters; for example, in photovoltaic mode, the operation graphic corresponding to the irradiance parameter is the sun. The display state of the operation graphic can be the state presented when the operation graphic is displayed, such as the display state of the sun's brightness, water flow rate, and water level. The parameter value is the value of the adjustable parameter. Optionally, one way to display the operation graphic and parameter value is to query the preset operation graphic and preset parameter value corresponding to each adjustable parameter, display the preset operation graphic at a random position on the display interface, and display the preset parameter value at a preset orientation corresponding to the preset operation graphic. By converting parameters into intuitive visual images, users can quickly understand and operate them. An example could be that, with the preset orientation below, in the basic mode, the operation graphic corresponding to the current parameter is water flow; when the water flow is displayed at a random position on the display interface, the parameter value corresponding to the current parameter is simultaneously displayed below the water flow.
[0052] In one embodiment, before playing the guided animation, each operation graphic and its corresponding adjustable parameter value are displayed on the display interface in their respective initial display states and initial parameter values. Optionally, one way to play the guided animation is to obtain the guided operation information of the operation graphics corresponding to each adjustable parameter, and then operate the operation graphics corresponding to each adjustable parameter in a random order based on the guided operation information to achieve the playback of the guided animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guided operation information. The guided operation information is used to characterize relevant information for guiding operations on the operation graphics, such as sliding up and down on water flow, clicking on a photovoltaic panel once, or sliding up and down on the sun. Replacing traditional operation manuals with guided animations clarifies operation steps and scope limitations, reduces additional learning, effectively avoids equipment errors caused by improper parameter input, provides good interactivity, and improves operational efficiency.
[0053] An exemplary example could be that, in the basic mode, the adjustable parameters are current, voltage, power, and resistance. The operation graphics corresponding to current and voltage are water flow, and the display status of the water flow includes flow rate and water level. The guidance operation information for the water flow is swipe up-swipe down-swipe left-swipe right. Swiping up and down indicates the water level rising and falling, while swiping left and right indicates the water flow speeding up and slowing down. The flow rate corresponds to the current value; the faster the flow rate, the larger the current value. The water level corresponds to the voltage value; the higher the water level, the larger the voltage value. The operation graphic corresponding to power is a fan blade, and the display status of the fan blade is rotation speed. The guidance operation information for the fan blade is swipe up first and then down, and swipe up and down indicate the rotation speed speeding up and slowing down. The faster the rotation speed, the greater the power. The operation graphic corresponding to resistance is a stone, and the display status of the stone is volume. The guidance operation information for the stone is swipe up first and then down, and swipe up and down indicate the volume increasing and decreasing. The larger the volume, the greater the resistance. Based on the corresponding guidance operation information, the water flow, fan blade, and stone are operated in a random order to achieve the playback of the guided animation.
[0054] Step S103: When the guiding animation ends, in response to the operation command on the operation graphic, adjust the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface based on the operation command. Different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0055] The operation command refers to the specific operation instructions issued to the operation graphic on the display interface. This operation command can be issued by the operator of the current power supply equipment. Different display states of the operation graphic synchronously correspond to different adjustable parameter values. For example, different flow rates of water synchronously correspond to different current values; the faster the flow rate, the greater the current. In one embodiment, controlling the operation state of an operation graphic can be achieved by activating the touchscreen operation function of the display interface, making the operation graphic operable. Touching the display interface allows for related operations on the operation graphic, such as touching the water flow and dragging the water level to adjust the voltage value. In another embodiment, controlling the operation state of an operation graphic can be achieved by displaying an operation gesture icon on the display interface, making the operation graphic operable. This gesture icon allows for related operations on the operation graphic, such as controlling the gesture icon to click on the photovoltaic panel to switch modes.
[0056] Optionally, one adjustment method may be to determine the adjustment information of the display state of the corresponding operation graphic in the display interface based on the operation instruction, adjust the display state of the operation graphic according to the adjustment information to obtain the updated state of the operation graphic, query the parameter value lookup table of the adjustable parameters corresponding to the operation graphic according to the updated state to obtain the corresponding updated parameter value, and adjust the parameter value of the adjustable parameter to the updated parameter value. Here, the adjustment information is used to characterize the information used to adjust the display state of the operation graphic, such as the degree of adjustment and the adjustment direction or switching state.
[0057] As described above, after selecting the test mode, the corresponding operation graphics and parameter values are displayed on the screen based on each adjustable parameter, and a guide animation corresponding to the test mode is played. Upon completion of the guide animation, in response to the operation command on the operation graphics, the display state of the corresponding operation graphics and the parameter values of the corresponding adjustable parameters on the screen are adjusted based on the operation command. By transforming parameters into intuitive visual objects through dynamic animation and clarifying the operation steps using guide animation, this solves the problems of complex and unintuitive operation, low efficiency, and low usability of setting parameters in the power supply device's operation interface in existing technologies. It makes the interface operation simpler and more intuitive, improving the usability and operational efficiency of the device.
[0058] Figure 2 A flowchart illustrating a power device interface interaction method that includes displaying operation graphics and parameter values, provided in this application embodiment, is shown below. Figure 2 As shown, it specifically includes:
[0059] Step S201: Obtain the selected test mode, wherein the test mode includes multiple different adjustable parameters of the power supply device.
[0060] Step S202: Query the pre-stored display information corresponding to each adjustable parameter. The pre-stored display information includes the operation graphic corresponding to the adjustable parameter, the display position of the operation graphic, the parameter value, and the display position of the parameter value. Display the operation graphic and the parameter value on the display interface according to the display position of the operation graphic and the display position of the parameter value.
[0061] The pre-stored display information is used to represent the relevant information related to the pre-stored adjustable parameters that is displayed on the display interface. The operation graphic display position is the position of the operation graphic on the display interface. Using this operation graphic display position, the corresponding operation graphic can be displayed on the display interface. The parameter value display position is the position of the adjustable parameter's parameter value on the display interface. Using this parameter value display position, the corresponding adjustable parameter's parameter value can be displayed on the display interface. An exemplary example could be that the adjustable parameters in a photovoltaic mode are irradiance, temperature, open-circuit voltage, maximum power point voltage, short-circuit current, maximum power point current, model type, and technology type. The system queries the operation graphic, operation graphic display position, parameter value, and parameter value display position corresponding to these eight adjustable parameters. Based on the operation graphic display position and the parameter value display position, the corresponding operation graphic and parameter value are displayed on the display interface. Figure 3 As shown, Figure 3 This is a schematic diagram of a display interface in a photovoltaic mode provided in an embodiment of this application. 01 is the operation graphic corresponding to irradiance; 02 is the parameter value of irradiance; 03 is the operation graphic corresponding to temperature; 04 is the parameter value of temperature; 05 is the operation graphic corresponding to model type; 06 is the parameter value of the corresponding model type; 07 is the operation graphic corresponding to technology type; 08 is the parameter value of technology type; 09 is the operation graphic corresponding to open-circuit voltage and maximum power point voltage; 10 is the parameter value of open-circuit voltage; 11 is the parameter value of maximum power point voltage; 12 is the operation graphic corresponding to short-circuit current and maximum power point current; 13 is the parameter value of short-circuit current; and 14 is the parameter value of maximum power point current. The operation graphics can be restricted according to the requirements of the values of each parameter, and a suitable graphic can be used to distinguish the reasonable parameter range that can be set. For example, the open-circuit voltage needs to be greater than the maximum power point voltage, and the short-circuit current needs to be greater than the maximum power point current.
[0062] Step S203: Play the guide animation corresponding to the test mode. The guide animation is a dynamic screen that shows the adjustment method of each adjustable parameter and the changes in the display status of the corresponding operation graphic.
[0063] Step S204: When the guiding animation ends, in response to the operation command of the operation graphic, adjust the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface based on the operation command. Different display states of the operation graphic correspond to different parameter values of the adjustable parameter.
[0064] As described above, after selecting the test mode, the system queries the pre-stored display information corresponding to each adjustable parameter. Based on the display positions of the operation graphics and parameter values in the pre-stored display information, the system displays the operation graphics and parameter values on the display interface. This solution transforms parameters into intuitive visual images, enabling users to quickly understand and operate the system.
[0065] Figure 4 A flowchart illustrating a power device interface interaction method including a guided animation playback method is provided in this application embodiment. Figure 4 As shown, it specifically includes:
[0066] Step S301: Obtain the selected test mode, wherein the test mode includes multiple different adjustable parameters of the power supply device.
[0067] Step S302: Display the corresponding operation graphics and parameter values on the display interface based on each adjustable parameter.
[0068] Step S303: Obtain the pre-stored guidance process of the test mode. The pre-stored guidance process includes the guidance order and guidance actions of each operation graphic. Based on the guidance actions, each operation graphic is operated in sequence according to the guidance order to realize the playback of the guidance animation. The display status of the operation graphic and the parameter values of the corresponding adjustable parameters change synchronously according to the guidance actions.
[0069] The pre-stored guidance process is used to represent the execution process information of the pre-stored guidance animation. The guidance sequence can be the order in which the guidance actions corresponding to the operation graphics are executed. The guidance actions can be operation information performed on the operation graphics, such as swiping up and then down, or clicking once. An exemplary example is that in the basic mode, the adjustable parameters are current, voltage, power, and resistance. The operation graphics corresponding to current and voltage are both water flow, and the guidance action for water flow is swipe up-slide down-swipe left-swipe right. The operation graphic corresponding to power is a fan blade, and the guidance action for the fan blade is swipe up and then down. The operation graphic corresponding to resistance is a stone, and the guidance action for the stone is swipe up and then down. The guidance sequence of each operation graphic is water flow-fan blade-stone. Therefore, the water flow is first swiped up, down, left, and right in sequence, then the fan blade is swiped up and down in sequence, and finally the stone is swiped up and down in sequence. The corresponding parameter values change synchronously when the water flow, fan blade, and stone are swiped.
[0070] Step S304: When the guiding animation ends, in response to the operation command on the operation graphic, adjust the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface based on the operation command. Different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0071] As described above, after acquiring the pre-stored guidance process of the test mode, the operation graphics are operated sequentially according to the guidance actions. This enables the playback of the guidance animation, the display status of the operation graphics, and the parameter values of the corresponding adjustable parameters to change synchronously according to the guidance actions. This solution replaces the traditional operation manual with guidance animation, which clarifies the operation steps and scope limitations, reduces additional learning, effectively avoids device errors caused by improper parameter input, provides good interactivity, and improves operational efficiency.
[0072] Figure 5 A flowchart illustrating a power device interface interaction method including adjusting display status and parameter values, provided in this application embodiment, is shown below. Figure 5 As shown, it specifically includes:
[0073] Step S401: Obtain the selected test mode, wherein the test mode includes multiple different adjustable parameters of the power supply device.
[0074] Step S402: Based on each adjustable parameter, display the corresponding operation graphics and parameter values on the display interface, and play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment method of each adjustable parameter and the change of the display state of the corresponding operation graphics.
[0075] Step S403: When the guiding animation ends, in response to the operation command on the operation graphic, if the operation attribute of the operation graphic is the sliding attribute, determine the display state of the operation graphic and the adjustment direction of the parameter value of the associated adjustable parameter according to the operation direction, and determine the adjustment intensity of the display state of the operation graphic and the adjustment value of the associated adjustable parameter according to the operation distance.
[0076] The operation attributes characterize the way the operation graphic is manipulated, such as sliding or clicking. Operation commands include operation direction and operation distance. The operation direction can be the direction of sliding the operation graphic, such as up, down, left, or right. The operation distance can be the distance the operation graphic is slid. The adjustment direction characterizes the direction of adjusting the display state of the operation graphic and the parameter value of the associated adjustable parameter, such as increasing, decreasing, raising, or lowering. The adjustment intensity can be the percentage by which the display state of the operation graphic is adjusted. The adjustment value characterizes the numerical value of the adjusted parameter. In one embodiment, determining the adjustment intensity and adjustment value can be done by querying a preset adjustment intensity lookup table corresponding to the display state of the operation graphic based on the operation distance to obtain the corresponding adjustment intensity, and then querying a preset adjustment value lookup table corresponding to the adjustable parameter based on the operation distance to obtain the corresponding adjustment value. In another embodiment, determining the adjustment intensity and adjustment value can be done by multiplying the operation distance by the unit intensity corresponding to the display state of the operation graphic to obtain the adjustment intensity, and then multiplying the operation distance by the unit value corresponding to the adjustable parameter to obtain the adjustment value.
[0077] An exemplary example could be that the current operating graphic is the sun, the sun's display status is brightness, the associated adjustable parameter is irradiance, the operating direction is upward sliding, and the operating distance is 3cm. Then, the adjustment direction of the sun's brightness and irradiance values is upward. Sliding the sun by 1cm changes the brightness adjustment intensity by 10% and the irradiance by 50W / m². Therefore, the current sun brightness adjustment intensity is calculated to be 30%, and the irradiance adjustment value is 150W / m².
[0078] Step S404: Based on the adjustment direction, adjustment intensity, and adjustment value, simultaneously adjust the display state of the operation graphic and the parameter values of the associated adjustable parameters on the display interface. Different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameters.
[0079] In one embodiment, after determining the display state of the operation graphic and the adjustment direction, adjustment intensity, and adjustment value of the associated adjustable parameter, the display state and the adjustable parameter are simultaneously adjusted on the display interface according to the adjustment direction, adjustment intensity, and adjustment value. An exemplary example could be that if the current operation graphic is a sun, the sun's display state is brightness, the associated adjustable parameter is irradiance, the adjustment direction is determined to be upward, the sun's brightness adjustment intensity is 30%, and the irradiance adjustment value is 150W / m², then the sun's brightness on the display interface is increased by 30%, and the irradiance value is increased by 150W / m².
[0080] As described above, when the guiding animation ends, in response to the operation command on the operation graphic, if the operation attribute of the operation graphic is sliding, the display state of the operation graphic and the adjustment direction of the associated adjustable parameter values are determined according to the operation direction. The adjustment intensity of the operation graphic's display state and the adjustment value of the associated adjustable parameters are determined according to the operation distance. Based on the adjustment direction, intensity, and value, the display state of the operation graphic and the parameter values of the associated adjustable parameters are simultaneously adjusted on the display interface. This solution, by responding to operation commands and dynamically adjusting the operation graphic and parameter values in real time, enables the setting of power supply device parameters.
[0081] Figure 6 A flowchart of another power device interface interaction method including adjusting display status and parameter values provided in this application embodiment is shown below. Figure 6 As shown, it specifically includes:
[0082] Step S501: Obtain the selected test mode, wherein the test mode includes multiple different adjustable parameters of the power supply device.
[0083] Step S502: Based on each adjustable parameter, display the corresponding operation graphics and parameter values on the display interface, and play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment method of each adjustable parameter and the change of the display state of the corresponding operation graphics.
[0084] Step S503: When the guiding animation ends, in response to the operation command on the operation graphic, if the operation attribute of the operation graphic is click attribute, query the preset adjustment lookup table corresponding to the operation graphic according to the number of clicks to obtain the display state to be switched of the operation graphic and the value of the parameter to be switched of the associated adjustable parameter.
[0085] The operation instructions include a number of clicks, which represents the number of times the operation graphic is clicked. Using this number of clicks, a preset adjustment lookup table corresponding to the operation graphic can be consulted to obtain the pending state of the operation graphic's display and the pending parameter values of the associated adjustable parameters. The preset adjustment lookup table can be a pre-set table comparing different pending states of the operation graphic with different number of clicks and different pending parameter values of the associated adjustable parameters. The pending state represents the display state to which the current display state of the operation graphic is to be switched. The pending parameter value is used to determine the parameter value to which the current parameter value of the adjustable parameter is to be switched. An exemplary example could be that the operation graphic is a photovoltaic panel 1, the display state of photovoltaic panel 1 is color, the associated adjustable parameter is model type, and the number of clicks is 2. A preset adjustment lookup table corresponding to photovoltaic panel 1 is shown in the table below:
[0086]
[0087] The above comparison table specifically describes the relationship between the number of clicks, the pending switching state of photovoltaic panel 1, and the pending switching parameter value of the model type. The details are as follows: When the number of clicks is 1, the pending switching state of photovoltaic panel 1 is white, and the pending switching parameter value of the model type is Sandia; when the number of clicks is 2, the pending switching state of photovoltaic panel 1 is yellow, and the pending switching parameter value of the model type is EN50530; when the number of clicks is 3, the pending switching state of photovoltaic panel 1 is green, and the pending switching parameter value of the model type is custom; when the number of clicks is 4, the pending switching state of photovoltaic panel 1 is blue, and the pending switching parameter value of the model type is static; when the number of clicks is 5, the pending switching state of photovoltaic panel 1 is purple, and the pending switching parameter value of the model type is dynamic.
[0088] If the number of clicks in the current operation command is 2, then the lookup table shows that the status to be switched is yellow and the parameter value to be switched is EN50530.
[0089] Step S504: Adjust the display state of the operation graphic to the state to be switched, and adjust the parameter values of the adjustable parameters associated with the operation graphic to the parameter values to be switched. Different display states of the operation graphic correspond synchronously to different parameter values of the adjustable parameters.
[0090] In one embodiment, after determining the desired switching state of the display state of the operation graphic and the desired switching parameter value of the associated adjustable parameter, the display state of the operation graphic is adjusted to the desired switching state, and the parameter value of the adjustable parameter associated with the operation graphic is adjusted to the desired switching parameter value. An exemplary example could be that the operation graphic is a photovoltaic panel 1, the display state of photovoltaic panel 1 is color, the current display color of photovoltaic panel 1 is black, the associated adjustable parameter is model type, and the currently displayed parameter value is Space. If it is determined that the desired switching state of photovoltaic panel 1 is yellow, and the desired switching parameter value of the model type is EN50530, then the color of photovoltaic panel 1 is switched to yellow, and the parameter value of the model type is switched to EN50530.
[0091] As described above, when the guiding animation ends, in response to the operation command on the operation graphic, if the operation attribute of the operation graphic is clickable, the system queries the preset adjustment lookup table corresponding to the operation graphic based on the number of clicks to obtain the pending switch state of the operation graphic's display state and the pending switch parameter values of the associated adjustable parameters. The display state of the operation graphic is then adjusted to the pending switch state, and the parameter values of the adjustable parameters associated with the operation graphic are adjusted to the pending switch parameter values. This solution, by responding to operation commands and dynamically adjusting the operation graphic and parameter values in real time, enables the setting of power supply device parameters.
[0092] Figure 7 This is a block diagram of a power supply device interface interaction device provided in an embodiment of this application. The system is used to execute a power supply device interface interaction method provided in the above embodiment, and has corresponding functional modules and beneficial effects for executing the method. Figure 7 As shown, the system specifically includes:
[0093] The acquisition module 101 is used to acquire the selected test mode, which includes multiple different adjustable parameters of the power supply device;
[0094] Display module 102 is used to display corresponding operation graphics and parameter values on the display interface based on each of the adjustable parameters;
[0095] The playback module 103 is used to play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment method of each of the adjustable parameters and the change of the display state of the corresponding operation graphics.
[0096] The adjustment module 104 is used to adjust the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface based on the operation command of the operation graphic when the guide animation ends, in response to the operation command of the operation graphic. The different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0097] As described above, after selecting the test mode, the corresponding operation graphics and parameter values are displayed on the screen based on each adjustable parameter, and a guide animation corresponding to the test mode is played. Upon completion of the guide animation, in response to the operation command on the operation graphics, the display state of the corresponding operation graphics and the parameter values of the corresponding adjustable parameters on the screen are adjusted based on the operation command. By transforming parameters into intuitive visual objects through dynamic animation and clarifying the operation steps using guide animation, this solves the problems of complex and unintuitive operation, low efficiency, and low usability of setting parameters in the power supply device's operation interface in existing technologies. It makes the interface operation simpler and more intuitive, improving the usability and operational efficiency of the device.
[0098] In one possible embodiment, the display module 102 is specifically used for:
[0099] Query the pre-stored display information corresponding to each of the adjustable parameters. The pre-stored display information includes the operation graphic corresponding to the adjustable parameter, the display position of the operation graphic, the parameter value, and the display position of the parameter value.
[0100] The operation graphic and the parameter value are displayed on the display interface according to the display position of the operation graphic and the display position of the parameter value.
[0101] In one possible embodiment, the playback module 103 is specifically used for:
[0102] Obtain the pre-stored guidance process of the test mode, the pre-stored guidance process including the guidance sequence and guidance actions of each of the operation graphics;
[0103] Based on the guided actions, each of the operation graphics is operated sequentially according to the guided order to realize the playback of the guided animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guided actions.
[0104] In one possible embodiment, the playback module 103 is further configured to:
[0105] Obtain the guidance operation information of the operation graphics corresponding to each of the adjustable parameters, and operate the operation graphics corresponding to each of the adjustable parameters in a random order based on the guidance operation information to realize the playback of the guidance animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guidance operation information.
[0106] In one possible embodiment, an operation state control module is further included, specifically for:
[0107] Enable the touch screen operation function of the display interface or display operation gesture icons on the display interface to make the operation graphics operable.
[0108] In one possible embodiment, the adjustment module 104 is specifically used for:
[0109] When the operation attribute of the operation graphic is a sliding attribute, the display state of the operation graphic and the adjustment direction of the parameter value of the associated adjustable parameter are determined according to the operation direction, and the adjustment intensity of the display state of the operation graphic and the adjustment value of the associated adjustable parameter are determined according to the operation distance.
[0110] According to the adjustment direction, the adjustment intensity, and the adjustment value, the display state of the operation graphic and the parameter values of the associated adjustable parameters are simultaneously adjusted on the display interface.
[0111] In one possible embodiment, the adjustment module 104 is further configured to:
[0112] When the operation attribute of the operation graphic is a click attribute, the preset adjustment lookup table corresponding to the operation graphic is queried according to the number of clicks to obtain the display state to be switched of the operation graphic and the value of the associated adjustable parameter to be switched.
[0113] Adjust the display state of the operation graphic to the state to be switched, and adjust the parameter values of the adjustable parameters associated with the operation graphic to the parameter values to be switched.
[0114] Figure 8 This is a schematic diagram of the structure of a power supply device interface interaction device provided in an embodiment of this application, such as... Figure 8 As shown, the device includes a processor 201, a memory 202, an input device 203, and an output device 204; the number of processors 201 in the device can be one or more. Figure 8 Taking a processor 201 as an example; the processor 201, memory 202, input device 203, and output device 204 in the device can be connected via a bus or other means. Figure 8Taking a bus connection as an example, the memory 202, as a computer-readable storage medium, can be used to store software programs, computer-executable programs, and modules, such as the program instructions or modules corresponding to a power supply device interface interaction method in this embodiment. The processor 201 executes various functional applications and data processing of the device by running the software programs, instructions, and modules stored in the memory 202, thereby realizing the aforementioned power supply device interface interaction method. The input device 203 can be used to receive input digital or character information and generate key signal inputs related to user settings and function control of the device. The output device 204 may include a display screen or other display device.
[0115] This application embodiment also provides a storage medium containing computer-executable instructions, which, when executed by a computer processor, are used to perform a power device interface interaction method, the method comprising:
[0116] Obtain the selected test mode, which includes multiple different adjustable parameters of the power supply device;
[0117] Based on each of the adjustable parameters, the corresponding operation graphics and parameter values are displayed on the display interface, and the guide animation corresponding to the test mode is played. The guide animation is a dynamic screen showing the adjustment method of each of the adjustable parameters and the change of the display state of the corresponding operation graphics.
[0118] When the guiding animation ends, in response to the operation command on the operation graphic, the display state of the corresponding operation graphic in the display interface and the parameter value of the corresponding adjustable parameter are adjusted based on the operation command, wherein different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
[0119] It is worth noting that in the embodiments of the above power device interface interaction method system, the various units and modules included are only divided according to functional logic, but are not limited to the above division, as long as the corresponding functions can be achieved; in addition, the specific names of each functional unit are only for easy differentiation and are not used to limit the protection scope of the embodiments of this application.
[0120] Note that the above are merely preferred embodiments and the technical principles applied in this application. Those skilled in the art will understand that the embodiments of this application are not limited to the specific embodiments described herein, and various obvious changes, readjustments, and substitutions can be made by those skilled in the art without departing from the protection scope of the embodiments of this application. Therefore, although the embodiments of this application have been described in detail through the above embodiments, the embodiments of this application are not limited to the above embodiments. More other equivalent embodiments may be included without departing from the concept of the embodiments of this application, and the scope of the embodiments of this application is determined by the scope of the appended claims.
Claims
1. A power device interface interaction method, characterized by, The method includes: Obtain the selected test mode, which includes multiple different adjustable parameters of the power supply device; Based on each of the adjustable parameters, the corresponding operation graphics and parameter values are displayed on the display interface, and a guide animation corresponding to the test mode is played. The guide animation is a dynamic screen showing the adjustment method of each of the adjustable parameters and the change of the display state of the corresponding operation graphics. Playing the guide animation corresponding to the test mode includes: obtaining the pre-stored guide process of the test mode, the pre-stored guide process including the guide order and guide actions of each of the operation graphics, and performing operations on each of the operation graphics in the order of the guide actions to realize the playback of the guide animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guide actions. The operation graphics are interactive graphic elements used to represent the corresponding adjustable parameters and to adjust the adjustable parameters. When the guided animation ends, the touch screen operation function of the display interface is turned on or the operation gesture icon is displayed on the display interface to make the operation graphic operable. In response to the operation command of the operation graphic, the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter in the display interface are adjusted based on the operation command. Different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
2. The power device interface interaction method of claim 1, wherein, The step of displaying corresponding operation graphics and parameter values on the display interface based on each of the adjustable parameters includes: Query the pre-stored display information corresponding to each of the adjustable parameters. The pre-stored display information includes the operation graphic corresponding to the adjustable parameter, the display position of the operation graphic, the parameter value, and the display position of the parameter value. The operation graphic and the parameter value are displayed on the display interface according to the display position of the operation graphic and the display position of the parameter value.
3. The power device interface interaction method of any one of claims 1-2, wherein, The playback of the guide animation corresponding to the test mode includes: Obtain the guidance operation information of the operation graphics corresponding to each of the adjustable parameters, and operate the operation graphics corresponding to each of the adjustable parameters in a random order based on the guidance operation information to realize the playback of the guidance animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guidance operation information.
4. The power device interface interaction method of any one of claims 1-2, wherein, The operation instructions include the operation direction and operation distance. Adjusting the display state of the corresponding operation graphic and the parameter values of the corresponding adjustable parameters on the display interface based on the operation instructions includes: When the operation attribute of the operation graphic is a sliding attribute, the display state of the operation graphic and the adjustment direction of the parameter value of the associated adjustable parameter are determined according to the operation direction, and the adjustment intensity of the display state of the operation graphic and the adjustment value of the associated adjustable parameter are determined according to the operation distance. According to the adjustment direction, the adjustment intensity, and the adjustment value, the display state of the operation graphic and the parameter values of the associated adjustable parameters are simultaneously adjusted on the display interface.
5. The power supply device interface interaction method according to any one of claims 1-2, characterized in that, The operation instruction includes the number of clicks, and the step of adjusting the display state of the corresponding operation graphic in the display interface and the parameter value of the corresponding adjustable parameter based on the operation instruction includes: When the operation attribute of the operation graphic is a click attribute, the preset adjustment lookup table corresponding to the operation graphic is queried according to the number of clicks to obtain the display state to be switched of the operation graphic and the value of the associated adjustable parameter to be switched. Adjust the display state of the operation graphic to the state to be switched, and adjust the parameter values of the adjustable parameters associated with the operation graphic to the parameter values to be switched.
6. A power device interface interaction system characterized by, include: An acquisition module is used to acquire a selected test mode, which includes multiple different adjustable parameters of the power supply device; The display module is used to display the corresponding operation graphics and parameter values on the display interface based on each of the adjustable parameters; The playback module is used to play the guide animation corresponding to the test mode. The guide animation is a dynamic screen showing the adjustment methods of each of the adjustable parameters and the changes in the display state of the corresponding operation graphics. Specifically, the playback module is used to: obtain the pre-stored guide process of the test mode, the pre-stored guide process includes the guide order and guide actions of each of the operation graphics, and perform operations on each of the operation graphics in the order of the guide actions to realize the playback of the guide animation. The display state of the operation graphics and the parameter values of the corresponding adjustable parameters change synchronously according to the guide actions. The operation graphics are interactive graphic elements used to represent the corresponding adjustable parameters and to adjust the adjustable parameters. The adjustment module is used to enable the touch screen operation function of the display interface or display operation gesture icons on the display interface when the guide animation ends, so that the operation graphic is in an operable state. In response to the operation command of the operation graphic, the module adjusts the display state of the corresponding operation graphic and the parameter value of the corresponding adjustable parameter on the display interface based on the operation command. The different display states of the operation graphic synchronously correspond to different parameter values of the adjustable parameter.
7. A power device interface interaction device, the device comprising: One or more processors; A storage device for storing one or more programs, which, when executed by one or more processors, cause the one or more processors to implement the power device interface interaction method as described in any one of claims 1-5.
8. A storage medium storing computer-executable instructions, which, when executed by a computer processor, are used to perform the power device interface interaction method as described in any one of claims 1-5.