Unlocking test system and unlocking test method
By designing an unlocking test system and method, and establishing a mapping relationship between cylinder components and solenoid valve components, quantitative testing of various unlocking methods of smart door locks was achieved. This solved the problem of insufficient testing in existing technologies and improved the accuracy of test results and the evaluation of unlocking performance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- GUANGZHOU ANYKA MICROELECTRONICS CO LTD
- Filing Date
- 2025-01-13
- Publication Date
- 2026-07-14
AI Technical Summary
Existing technologies for testing smart door locks lack diversity and comprehensiveness, resulting in insufficient testing and difficulty in reflecting actual unlocking performance.
An unlocking test system and method were designed. By establishing a preset mapping relationship between unlocking test parameters and driving parameters, and utilizing a cylinder assembly, a solenoid valve assembly, and a data processing module, quantitative testing of various unlocking methods of smart door locks was achieved, including button, fingerprint, and antenna unlocking.
The test scenarios were enriched, the data reference value of the test results was improved, the accuracy of the unlocking performance evaluation was enhanced, and the test effect was optimized.
Smart Images

Figure CN122385155A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of testing technology for smart door locks, and in particular to unlocking testing systems and unlocking testing methods. Background Technology
[0002] With rising economic standards, many users are choosing smart locks to improve their quality of life. Common unlocking methods for smart locks include buttons, fingerprints, card swipes, or remote unlocking. Before leaving the factory, smart locks typically undergo unlocking tests, which are a crucial part of quality control.
[0003] Generally, in related technologies, different unlocking methods are combined with different unlocking test methods. For example, for button or fingerprint unlocking, single-point touch or pressing is mostly used for direct testing, and the touch or pressing force is mostly random. For card or mobile phone unlocking, which uses electromagnetic signals, the card or mobile phone unlocking tool is usually placed at a fixed distance to measure the unlocking performance of the smart door lock.
[0004] However, the unlocking methods in related technologies are still qualitative testing methods, that is, most of them use fixed test conditions to uniformly test smart door locks. The test coverage scenarios are insufficient, resulting in insufficient testing and relatively thin test data, which is difficult to reflect the actual unlocking performance of smart door locks. Summary of the Invention
[0005] Therefore, it is necessary to address the problem that qualitative testing of smart lock unlocking is insufficient and fails to reflect the actual unlocking performance of smart locks, and to provide an unlocking test system and unlocking test method.
[0006] An unlocking test system for testing the unlocking performance of a smart door lock, the unlocking test system comprising:
[0007] Support components;
[0008] A support bracket is connected to the support assembly; the support bracket is used to install a smart door lock.
[0009] An unlocking module is movably connected to the support component, and the unlocking module is capable of telescopic movement relative to the support component along a first direction;
[0010] The data processing module is used to obtain the driving parameters that correspond one-to-one with the unlocking test parameters in the preset mapping relationship; wherein, the unlocking module is used to unlock the unlocking area of the smart door lock according to the driving parameters.
[0011] In one embodiment, the unlocking module includes a pressure unlocking component, which includes a cylinder assembly and an unlocking member; the cylinder assembly is connected and cooperates with the unlocking member, and the cylinder assembly is used to drive the unlocking member to extend and retract along the first direction, so that the unlocking member presses against the unlocking area to unlock.
[0012] In one embodiment, the unlocking module further includes a solenoid valve assembly, which is connected to the cylinder assembly in a one-to-one correspondence. The solenoid valve assembly is communicatively connected to the data processing module, and is used to receive the driving parameters to adjust the airflow of the cylinder assembly.
[0013] In one embodiment, the unlocking component includes multiple button connectors, and the unlocking area includes multiple unlocking buttons; the multiple button connectors are configured one-to-one with the multiple unlocking buttons; the cylinder assembly includes multiple first cylinder assemblies, and the multiple first cylinder assemblies are connected to the multiple button connectors in a transmission manner; the solenoid valve assembly includes a first solenoid valve; the first solenoid valve is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters.
[0014] In one embodiment, the unlocking element includes a flexible fingerprint connector; the unlocking area includes a fingerprint unlocking area; the cylinder assembly includes a second cylinder assembly, which is operatively connected to the flexible fingerprint connector, and is used to drive the flexible fingerprint connector to extend and retract along the first direction, so that the flexible fingerprint connector unlocks the fingerprint unlocking area; the solenoid valve assembly includes a second solenoid valve, which is communicatively disposed in the second cylinder assembly, and is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters.
[0015] In one embodiment, the unlocking module is movably connected to the support component, and the unlocking module is movable relative to the support component along a second direction, so that the orthographic projection area of the unlocking member on the unlocking area is adjustable, and the pressing area of the unlocking member against the unlocking area is adjustable; the second direction is perpendicular to the first direction.
[0016] And / or, the support bracket is movably connected to the smart lock so that the smart lock can move relative to the support bracket in a third direction upward, so that the orthogonal projection area of the unlocking module on the unlocking area is adjustable, and the pressing area of the unlocking member against the unlocking area is adjustable; the third direction is perpendicular to the first direction.
[0017] In one embodiment, the unlocking module is tilted relative to the first direction;
[0018] And / or, at least a portion of the load-bearing supports are inclined relative to the first direction.
[0019] In one embodiment, the unlocking module includes an antenna unlocking component, which includes an electromagnetic unlocking element and a driving component. The unlocking area includes an antenna unlocking area. The electromagnetic unlocking element is used to power-unlock the antenna unlocking area. The driving component is used to drive the electromagnetic unlocking element to extend and retract along the first direction. The driving component is communicatively connected to the data processing module so that the driving component receives the driving parameters and adjusts the relative distance between the electromagnetic unlocking element and the antenna unlocking area according to the driving parameters.
[0020] In one embodiment, the driving assembly includes a third cylinder assembly and a sliding assembly; the third cylinder assembly is drively connected to the electromagnetic unlocking member, and the third cylinder assembly is used to drive the electromagnetic unlocking member to extend and retract along the first direction; the sliding assembly extends along the first direction, and the third cylinder assembly is slidably disposed on the sliding assembly, so that the relative distance between the third cylinder assembly and the antenna unlocking area is adjustable, thereby making the relative distance between the electromagnetic unlocking member and the antenna unlocking area adjustable.
[0021] An unlocking test method includes:
[0022] Obtain multiple different unlock test parameters;
[0023] Based on the preset mapping relationship, obtain multiple driving parameters that correspond one-to-one with the multiple unlock test parameters;
[0024] The unlocking module is driven multiple times according to the multiple driving parameters, so that the unlocking module unlocks the unlocking area;
[0025] Determine whether the smart lock has been successfully unlocked. If it has been successfully unlocked, the smart lock is considered to be in a normal unlocking state; otherwise, the smart lock is considered to be in an abnormal unlocking state.
[0026] In one embodiment, the unlocking test method further includes: obtaining the lock type of the smart lock; obtaining a preset unlocking range based on the lock type; and obtaining the plurality of different unlocking test parameters based on the preset unlocking range.
[0027] And / or, the multiple different unlocking test parameters show a gradual changing trend.
[0028] In one embodiment, the unlocking module includes a cylinder assembly and an unlocking component; the cylinder assembly is connected to the unlocking component, and the cylinder assembly is used to drive the unlocking component to extend and retract along the first direction, so that the unlocking component presses against the unlocking area to unlock; the unlocking test method includes:
[0029] The unlocking test parameters include at least one of the contact pressure value between the unlocking component and the unlocking area and the contact area value between the unlocking component and the unlocking area.
[0030] In one embodiment, the unlocking module further includes a solenoid valve assembly, which is connected to each of the cylinder assemblies in a one-to-one correspondence. The solenoid valve assembly is communicatively connected to the data processing module, and is used to receive the driving parameters to adjust the airflow of the cylinder assembly; the unlocking test method includes:
[0031] The preset mapping relationship includes a first mapping relationship; the driving parameters include the solenoid valve opening value;
[0032] Obtain multiple different unlock test parameters;
[0033] Based on the first mapping relationship, obtain multiple solenoid valve opening values that correspond one-to-one with the multiple unlocking test parameters;
[0034] The solenoid valve assembly is opened to the solenoid valve opening value so that the cylinder assembly is pressed against the unlocking area with a pressure that reaches the unlocking test parameter.
[0035] In one embodiment, the unlocking component includes multiple button connectors, and the unlocking area includes multiple unlocking buttons; the multiple button connectors are configured one-to-one with the multiple unlocking buttons; the cylinder assembly includes multiple first cylinder assemblies, and the multiple first cylinder assemblies are connected to the multiple button connectors in a corresponding transmission manner; the solenoid valve assembly includes multiple first solenoid valves; the first solenoid valves are connected in communication with the first cylinder assembly, and the first solenoid valves are communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters;
[0036] The unlocking test method includes:
[0037] The unlocking test parameters include the contact pressure value; the first mapping relationship includes a first sub-mapping relationship; the driving parameters include a first opening value;
[0038] Obtain the unlocking order, and obtain multiple different contact pressure values;
[0039] Based on the first sub-mapping relationship, obtain a plurality of first opening values that correspond one-to-one with the plurality of contact pressure values;
[0040] According to the unlocking order, multiple first solenoid valves are driven sequentially to open to a first opening value, so that multiple first cylinder assemblies sequentially drive multiple button connectors to press against the corresponding unlocking button to unlock, and the pressure of the button connector against the unlocking area reaches the contact pressure value.
[0041] In one embodiment, the unlocking component includes a flexible fingerprint connector; the unlocking area includes a fingerprint unlocking area; the cylinder assembly includes a second cylinder assembly, the solenoid valve assembly includes a second solenoid valve, the second cylinder assembly is pultrusively connected to the flexible fingerprint connector, the second cylinder assembly is used to drive the flexible fingerprint connector to extend and retract along the first direction, so that the flexible fingerprint connector unlocks the fingerprint unlocking area; the solenoid valve assembly includes a second solenoid valve, the second solenoid valve is connected in communication with the second cylinder assembly, the second solenoid valve is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters; the unlocking test method includes:
[0042] The unlocking test parameters include the contact area value; the first mapping relationship includes a second sub-mapping relationship; the solenoid valve opening value includes a second opening value;
[0043] Obtain multiple different contact area values;
[0044] According to the second sub-mapping relationship, obtain a plurality of second opening values that correspond one-to-one with the plurality of contact area values;
[0045] Open the second solenoid valve to the second opening value so that the fingerprint connector presses against the fingerprint unlocking area to reach the contact area value.
[0046] In one embodiment, the unlocking module is movably connected to the support component, and the unlocking module is movable relative to the support component along a second direction; the second direction is perpendicular to the first direction; the unlocking test method includes:
[0047] The unlocking test parameters include the contact area value; the preset mapping relationship includes a second mapping relationship; the driving parameters include a first sliding distance value;
[0048] Obtain multiple different contact area values;
[0049] According to the second mapping relationship, a plurality of first sliding distance values are obtained that correspond one-to-one with the plurality of contact area values;
[0050] The unlocking module is driven to move along the second direction according to a plurality of first sliding distance values, so that the orthogonal projection area of the unlocking module on the bearing support is adjustable, and the pressing area of the unlocking member against the unlocking area reaches the contact area value.
[0051] And / or,
[0052] The support bracket is movably connected to the smart lock, so that the smart lock can move upward relative to the support bracket along a third direction; the third direction is perpendicular to the first direction.
[0053] The unlocking test method includes:
[0054] The unlocking test parameters include the contact area value; the preset mapping relationship includes a third mapping relationship; the driving parameters include a second sliding distance value;
[0055] Obtain multiple different contact area values;
[0056] According to the third mapping relationship, obtain a plurality of second sliding distance values that correspond one-to-one with the plurality of contact area values;
[0057] The support is driven to move along the third direction according to multiple second sliding distance values, so that the orthogonal projection area of the unlocking module on the support is adjustable, and the pressing area of the unlocking member against the unlocking area reaches the contact area value.
[0058] In one embodiment, the unlocking module includes an antenna unlocking component, which includes an electromagnetic unlocking element and a driving component; the unlocking area includes an antenna unlocking area; the electromagnetic unlocking element is used to power-unlock the antenna unlocking area; the unlocking test method includes:
[0059] The unlocking test parameters include a communication distance value; the preset mapping relationship includes a fourth mapping relationship; the driving parameters include a movement distance value;
[0060] Obtain multiple different communication distance values;
[0061] According to the fourth mapping relationship, obtain multiple movement distance values corresponding to the multiple communication distance values;
[0062] The driving component is driven according to a plurality of the moving distance values to drive the electromagnetic unlocking component to extend and retract along the first direction, so that the relative distance between the electromagnetic unlocking component and the antenna unlocking area reaches the communication distance value.
[0063] The aforementioned unlocking test system and method, through different unlocking test parameters as described in the embodiments, confirm different test conditions and scenarios. Based on a preset mapping relationship, driving parameters corresponding to the unlocking test parameters can be obtained. The driving module drives the unlocking module according to these driving parameters, enabling the unlocking module to unlock the unlocking area under the corresponding unlocking test parameters. This allows for the assessment of the smart lock's unlocking performance under those unlocking test parameters. Thus, using different unlocking test parameters enriches the testing scenarios for smart locks.
[0064] Furthermore, unlike related technologies that use fixed driving parameters to conduct qualitative unlocking tests, this application establishes a preset mapping relationship between unlocking test parameters and driving parameters. By obtaining different values of driving parameters through different unlocking test parameters, it is possible to quantitatively test the unlocking of smart door locks, optimize the test results, and the test results can better reflect the relationship between unlocking test parameters and unlocking performance, thereby improving the data reference value of the test results. Attached Figure Description
[0065] Figure 1 This is a schematic diagram of the unlocking test system in one embodiment.
[0066] Figure 2 for Figure 1 A magnified schematic diagram of structure A in the middle.
[0067] Figure 3 This is a flowchart illustrating the unlocking test method in one embodiment.
[0068] Figure 4 This is a schematic diagram of the unlocking area in one embodiment.
[0069] Figure 5 This is a schematic diagram illustrating the cooperation between the data processing module and the unlocking module in one embodiment.
[0070] Figure 6 This is a flowchart illustrating an unlocking test method in one embodiment, where the unlocking module and the unlocking area are pressed together for unlocking.
[0071] Figure 7 for Figure 6 The diagram shows a flowchart of the unlocking test method in one embodiment.
[0072] Figure 8 for Figure 6 The diagram shows a flowchart of the unlocking test method in another embodiment.
[0073] Figure 9 This is a flowchart illustrating an unlocking test method when the unlocking module and the unlocking area are in active coordination, as shown in another embodiment.
[0074] Figure 10This is a flowchart illustrating an unlocking test method for the electromagnetic unlocking component and the antenna unlocking area in one embodiment.
[0075] Explanation of reference numerals in the attached figures:
[0076] 100. Unlocking test system; 110. Support component; 120. Bearing support; 120a. Slide groove; 120b. Sliding component; 130. Unlocking module; 131. Press-to-unlock component; 1311. Cylinder assembly; 1311a. First cylinder assembly; 1311b. Second cylinder assembly; 1312. Unlocking component; 1312a. Button connector; 1312b. Fingerprint connector; 1313. Solenoid valve assembly; 1313a. First solenoid valve; 1313b. Second solenoid valve; 132. Antenna unlocking component; 140. Data processing module; 200. Unlocking area; 201. Unlock button; 202. Fingerprint unlocking area; X, First direction; Y, Second direction; Z, Third direction. Detailed Implementation
[0077] To make the above-mentioned objectives, features, and advantages of this application more apparent and understandable, the specific embodiments of this application are described in detail below with reference to the accompanying drawings. Many specific details are set forth in the following description to provide a thorough understanding of this application. However, this application can be implemented in many other ways different from those described herein, and those skilled in the art can make similar modifications without departing from the spirit of this application. Therefore, this application is not limited to the specific embodiments disclosed below.
[0078] See Figure 1 as well as Figure 2 , Figure 1 A schematic diagram of the structure of an unlocking test system 100 according to an embodiment of the present application is shown. The unlocking test system 100 provided in an embodiment of the present application includes a support component 110, a bearing support 120, an unlocking module 130, and a data processing module 140.
[0079] Both the support bracket 120 and the unlocking module 130 are mounted on the support assembly 110. The support bracket 120 is used to install the smart door lock. The data processing module 140 is used to obtain the driving parameters that correspond one-to-one with the unlocking test parameters in the preset mapping relationship. Here, the first direction X can be... Figure 1 The height direction is shown in the figure.
[0080] Specifically, the unlocking test system 100 described above can be used to perform the following unlocking test methods. For example... Figure 3 as well as Figure 4 As shown, the unlocking test methods include:
[0081] S1. Obtain multiple different unlock test parameters. Different unlock test parameters represent different test conditions.
[0082] In one example, the unlocking test parameters include at least one of the following: contact area parameter, installation distance parameter, and contact pressure parameter.
[0083] S2. Based on the preset mapping relationship, obtain multiple driving parameters that correspond one-to-one with multiple unlock test parameters.
[0084] S3. The unlocking module 130 is driven multiple times according to multiple driving parameters, so that the unlocking module 130 unlocks the unlocking area 200.
[0085] That is, based on different unlocking test parameters, corresponding driving parameters can be obtained. When the driving module drives the unlocking module 130 to unlock according to the driving parameters, the unlocking area 200 and the unlocking module 130 can meet the corresponding unlocking test parameters. Specifically, in one example, the unlocking area 200 can be any one or a combination of the unlocking button 201, the fingerprint unlocking area 202, or the antenna unlocking area.
[0086] S4. Determine if the smart lock has unlocked successfully. If unlocked successfully, the smart lock is considered to be in a normal unlocking state. Otherwise, the smart lock is considered to be in an abnormal unlocking state.
[0087] Specifically, the drive module sequentially drives the unlocking module 130 according to multiple drive parameters. Each time the unlocking module 130 is driven according to the drive parameters, it checks whether the smart lock has unlocked successfully. If unlocking is successful, it means that the smart lock can unlock normally under the corresponding unlocking test parameters. If unlocking fails, it means that the smart lock cannot unlock normally under the corresponding unlocking test and is in an abnormal unlocking state. In this case, if any unlocking test parameter fails to enable the smart lock to unlock normally, it means that there is a problem with the unlocking performance of the smart lock, and the smart lock still needs to be returned to the factory for repair and adjustment.
[0088] By using different unlocking test parameters in the above embodiments, different test conditions and scenarios can be identified. Based on a preset mapping relationship, driving parameters corresponding to the unlocking test parameters can be obtained. By driving the unlocking module 130 according to these parameters, the unlocking module 130 can unlock the unlocking area 200 under the corresponding unlocking test parameters. This allows for the assessment of the smart lock's unlocking performance under those unlocking test parameters. Thus, using different unlocking test parameters enriches the test scenarios for the smart lock.
[0089] Furthermore, unlike related technologies that use fixed driving parameters to conduct qualitative unlocking tests, this application establishes a preset mapping relationship between unlocking test parameters and driving parameters. By obtaining different values of driving parameters through different unlocking test parameters, it is possible to quantitatively test the unlocking of smart door locks, optimize the test results, and the test results can better reflect the relationship between unlocking test parameters and unlocking performance, thereby improving the data reference value of the test results.
[0090] It should be noted that the number of unlocking modules 130 in the above embodiments may include one unlocking component or may include multiple unlocking components. In addition, the type of unlocking component may be a pressure unlocking component 131 (also called a contact unlocking component), or an antenna unlocking component 132, or a combination thereof, etc., without much limitation here.
[0091] In some implementations, see back Figure 2 The unlocking module 130 includes a pressure unlocking component 131, which includes a cylinder assembly 1311 and an unlocking member 1312. The cylinder assembly 1311 is connected and cooperates with the unlocking member 1312. The cylinder assembly 1311 is used to drive the unlocking member 1312 to extend and retract along the first direction X, so that the unlocking member 1312 presses and unlocks the unlocking area 200.
[0092] The pressure-activated unlocking component 131 can be, but is not limited to, a fingerprint unlocking component, or a button unlocking component, etc. Specifically, the unlocking test method includes:
[0093] The unlocking test parameters include at least one of the contact pressure value between the unlocking component 1312 and the unlocking area 200 and the contact area value between the unlocking component 1312 and the unlocking area 200.
[0094] That is, the driving parameters can be driving parameters for driving the unlocking connector to move telescopically along the first direction X, so that a contact pressure value corresponding to the unlocking test parameters is generated between the pressing unlocking connector and the unlocking area 200. Alternatively, they can be driving parameters for driving the unlocking member 1312 to move along other directions (such as the width direction or length direction in the figure), so that the unlocking member 1312 and the unlocking area 200 generate a contact area corresponding to the unlocking test parameters when they telescopically extend and retract in the first direction X.
[0095] Thus, the cylinder assembly 1311 drives the key connector 1312a to unlock. The cylinder assembly 1311 has a fast transmission speed and precise transmission, which helps to improve unlocking efficiency. At the same time, unlike the drive components of robotic arms, the cylinder assembly 1311 has a lower setup cost, which helps to reduce the processing cost of the unlocking test system 100. Furthermore, since the stroke of the cylinder assembly 1311 is relatively fixed (which can be understood as a constant value), the complexity of the preset mapping relationship can be reduced, which helps to improve calculation efficiency, thereby improving unlocking test efficiency.
[0096] In one embodiment, see Figure 5 The unlocking module 130 also includes a solenoid valve assembly 1313, which is connected to the cylinder assembly 1311 in a one-to-one correspondence. The solenoid valve assembly 1313 is communicatively connected to the data processing module 140 and is used to receive drive parameters to adjust the airflow of the cylinder assembly 1311. That is, in this embodiment, the airflow of the cylinder assembly 1311 is adjusted by the opening degree of the solenoid valve assembly 1313, so that the cylinder assembly 1311 will generate different impulses to the unlocking member 1312 under a fixed stroke. When the airflow is larger, the pressure on the unlocking member 1312 from the cylinder assembly 1311 is greater, and thus the abutment force applied by the unlocking member 1312 to the unlocking area 200 is also greater. Conversely, when the airflow is smaller, the pressure on the unlocking member 1312 from the cylinder assembly 1311 is smaller, and thus the abutment force applied by the unlocking member 1312 to the unlocking area 200 is also smaller.
[0097] like Figure 6 As shown, the unlocking test methods specifically include:
[0098] The preset mapping relationship includes the first mapping relationship. The drive parameters include the solenoid valve opening value.
[0099] S11. Obtain multiple different unlocking test parameters. These parameters can be the contact pressure value and the contact area value.
[0100] S21. Obtain multiple solenoid valve opening values that correspond one-to-one with multiple unlocking test parameters according to the first mapping relationship.
[0101] S31. Open the solenoid valve assembly 1313 to the solenoid valve opening value so that the cylinder assembly 1311 is pressed against the unlocking area 200 to reach the unlocking test parameter.
[0102] It is understood that in this embodiment, the unlocking test parameters can be adjusted by adjusting the opening value of the solenoid valve. When the cylinder assembly 1311 is working, within a certain range, the air flow of the cylinder assembly 1311 is positively correlated with the contact pressure value or contact area value. At the same time, unlike adjusting the air supply of the cylinder assembly 1311 to adjust the air flow, adjusting the air flow by adjusting the opening of the solenoid valve assembly 1313 is a simpler and easier-to-operate method.
[0103] For ease of explanation, the following section will describe different unlocking test parameters using both fingerprint unlocking and button unlocking components.
[0104] In one embodiment, combined with Figure 2 as well as Figure 7 The pressure-activated unlocking component 131 includes a button-activated unlocking component. Among them, such as... Figure 4 As shown, the unlocking area 200 includes a region for connecting to the button unlocking component for button unlocking; for ease of description, this region is referred to as the "unlock button 201". The unlock button 201 may include components such as capacitors and sensors to sense pressure applied to the button connector.
[0105] Specifically, the unlocking component 1312 includes multiple button connectors 1312a, which are configured one-to-one with multiple unlocking buttons 201 in the unlocking area 200. The cylinder assembly 1311 includes multiple first cylinder assemblies 1311a, which are connected to the multiple button connectors 1312a in a transmission manner.
[0106] Furthermore, the solenoid valve assembly 1313 includes a first solenoid valve 1313a. The first solenoid valve 1313a is connected to the first cylinder assembly 1311a and is communicatively connected to the data processing module 140 to receive drive parameters and adjust the opening degree according to the drive parameters.
[0107] like Figure 7 As shown, the unlocking test methods at this time include:
[0108] The unlocking test parameters include the contact pressure value. The first mapping relationship includes the first sub-mapping relationship. The driving parameters include the first opening value.
[0109] S001. Obtain the unlocking order;
[0110] S111: Obtain multiple different contact pressure values.
[0111] S211. Based on the first sub-mapping relationship, obtain multiple first opening values that correspond one-to-one with multiple contact pressure values.
[0112] Understandably, when the first cylinder assembly 1311a is operating, within a certain range, the airflow of the first cylinder assembly 1311a is positively correlated with the contact pressure value. Furthermore, unlike adjusting the compression of the first compressor to regulate the airflow, regulating the airflow through the opening of the first solenoid valve 1313a is a simpler and easier-to-operate method. It should be noted that the contact pressure value is the independent variable of the first preset mapping relationship, and the first opening value is the dependent variable of the first preset mapping relationship. Since the values of multiple contact pressures are different, the opening ranges of the multiple first opening values are different.
[0113] S311. According to the unlocking order, drive multiple first solenoid valves 1313a in sequence to open the first solenoid valves 1313a to the first opening value, so that multiple first cylinder assemblies 1311a drive multiple button connectors 1312a to press and unlock the corresponding unlock button 201 in sequence according to the unlocking order, and make the pressure of the first cylinder assembly 1311a pressing against the unlocking area 200 reach the contact pressure value.
[0114] The unlocking sequence refers to the password sequence pre-stored in the smart lock. For example, if the unlocking sequence is 123456, the first cylinder assembly 1311a corresponding to the unlocking button 201 for "123456" will operate sequentially. Similarly, if the unlocking sequence is 000000, the first cylinder assembly 1311a corresponding to the unlocking button 201 for "0" will operate six times to complete the button unlocking.
[0115] Thus, this embodiment can test the relationship between unlocking pressure and unlocking performance of the button unlocking component. By selecting multiple contact pressure values, multiple test scenarios with different unlocking pressure values can be added, thereby enriching the testing performance of the button unlocking component.
[0116] In another embodiment, see back Figure 2 The unlocking module 130 includes a fingerprint unlocking component. For example... Figure 4 As shown, the unlocking area 200 includes a region for fingerprint unlocking via a fingerprint unlocking component; for ease of description, this region is referred to as the "fingerprint unlocking area 202". The fingerprint unlocking area 202 may contain a capacitive fingerprint reader or an optical fingerprint reader, etc.
[0117] Specifically, the unlocking component 1312 includes a fingerprint connector 1312b, and the cylinder assembly 1311 includes a second cylinder assembly 1311b. The second cylinder assembly 1311b is connected to the flexible fingerprint connector 1312b in a transmission manner. The second cylinder assembly 1311b is used to drive the flexible fingerprint connector 1312b to extend and retract along the first direction X, so that the flexible fingerprint connector 1312b unlocks the fingerprint unlocking area 202.
[0118] The fingerprint connector 1312b is equipped with a preset fingerprint, and the smart lock has a preset test fingerprint. When the fingerprint connector 1312b presses against the fingerprint area, the smart lock can compare the preset fingerprint and the test fingerprint to determine whether to unlock. The fingerprint unlocking component in the smart lock can be an optical fingerprint unlocking type or a capacitive fingerprint unlocking type, etc.
[0119] Furthermore, in some implementation scenarios, the unlocking component 1312 includes a flexible fingerprint connector 1312b, and the solenoid valve assembly 1313 includes a second solenoid valve 1313b. In this case, the unlocking test parameter can be at least one of the contact pressure value and the contact area value. Specifically, when the fingerprint connector 1312b is made of a flexible material, changes in the contact pressure value will cause changes in the contact area value. In this scenario, there is a mapping relationship between the contact area value and the contact pressure value, allowing them to be converted to each other. That is, a mapping relationship exists that allows the solenoid valve opening degree—contact pressure value—contact area value to be converted to each other.
[0120] like Figure 8 As shown, the unlocking test methods specifically include:
[0121] The unlock test parameters include the contact area value. The preset mapping parameters include the second sub-mapping parameter. The driving parameters include the second opening value.
[0122] S112, Obtain multiple different contact area values.
[0123] S212. Based on the second sub-mapping relationship, obtain multiple different second opening values that correspond one-to-one with multiple contact area values.
[0124] It is understandable that when the second cylinder assembly 1311b is working, within a certain range, the airflow rate of the second cylinder assembly 1311b is positively correlated with the contact pressure value; that is, within a certain range, the airflow rate of the second cylinder assembly 1311b is positively correlated with the contact pressure value. Similarly, unlike adjusting the compression rate of the second compressor to adjust the airflow rate, adjusting the airflow rate by the opening degree of the second solenoid valve 1313b is a simpler and easier-to-operate method.
[0125] S312. Open the second solenoid valve 1313b to the second opening value so that the fingerprint connector 1312b presses against the fingerprint unlocking area 202 to reach the contact area value.
[0126] Understandably, the fingerprint unlocking area 202 of a smart door lock typically uses fingerprint recognition for unlocking. Specifically, fingerprint recognition utilizes the optical or resistive properties of the fingerprint itself to form fingerprint features for identification. The area between the fingerprint mold connector 1312b and the fingerprint unlocking area 202 determines the range of fingerprint features that can be recognized. Based on this, in this embodiment, the contact area value can be converted into a second opening value through a second preset mapping relationship to adjust the opening of the second solenoid valve 1313b. This allows for adjustment of the contact pressure of the flexible fingerprint mold connector 1312b against the fingerprint unlocking area 202, enabling the fingerprint mold connector 1312b to undergo different deformations, thereby ensuring that the contact area between the flexible fingerprint mold connector 1312b and the fingerprint area reaches the contact area value.
[0127] In this way, the unlocking performance of the fingerprint unlocking area 202 of the smart door lock under different contact area values can be detected, enriching the detection scenarios and improving the detection accuracy. Furthermore, the second sub-mapping relationship is a mapping relationship between the contact area value and the second opening value, which reduces the calculation steps and eliminates the need to replace the contact pressure value with the contact area value, which helps to improve calculation efficiency and thus optimize the unlocking test efficiency.
[0128] When the unlock detection parameter is the contact area value, the button unlock component and the fingerprint unlock component in the above embodiments can also be implemented in other ways.
[0129] Furthermore, the cylinder stroke of the first cylinder assembly 1311a and the second cylinder assembly 1311b in the above embodiments can be a fixed value, which can be fixed in the following ways. In one example, the first cylinder assembly 1311a and the second cylinder assembly 1311b adopt a fixed stroke cylinder assembly 1311, that is, the extension and retraction stroke distance of the first cylinder assembly 1311a and the second cylinder assembly 1311b is fixed. In another example, the support assembly 110 also includes a second support assembly 110, which is used to install the unlocking module 130 at a preset height so that the extension and retraction stroke distance of the first cylinder assembly 1311a and the second cylinder assembly 1311b is fixed. In this way, by fixing the extension and retraction stroke distance of the first cylinder assembly 1311a and the second cylinder assembly 1311b, the model complexity of the first sub-mapping relationship and the second sub-mapping relationship can be reduced, the calculation difficulty can be reduced, and the detection efficiency during unlocking test can be improved.
[0130] In any embodiment of the above-described button unlocking component and fingerprint unlocking component, at least one of the unlocking module 130 and the support 120 is movable, so that the orthographic projection area of the unlocking module 130 on the support 120 is adjustable.
[0131] Specifically, in one embodiment, the unlocking module 130 is movably connected to the support component 110, and the unlocking module 130 is movable relative to the support component 110 along a second direction Y. The second direction Y is perpendicular to the first direction X.
[0132] like Figure 9 As shown, the unlocking test methods specifically include:
[0133] The unlocking test parameters include the contact area value. The preset mapping relationship includes the second mapping relationship. The driving parameters include the first sliding distance value.
[0134] S12. Obtain multiple different contact area values.
[0135] S22. Obtain multiple first sliding distance values that correspond one-to-one with multiple contact area values according to the second mapping relationship.
[0136] S32. Drive the unlocking module 130 to move relative to the sliding component along the second direction Y according to multiple first sliding distance values, so that the orthogonal projection area of the unlocking module 130 on the support 120 is adjustable, so that the pressing area of the unlocking member 1312 against the unlocking area 200 reaches the contact area value.
[0137] In another specific embodiment, the support 120 is movably connected to the smart lock, allowing the smart lock to move relative to the support 120 along a third direction Z. The third direction Z is perpendicular to the first direction X. The second direction Y and the third direction Z can be parallel or perpendicular; no further restrictions are imposed here.
[0138] Unlocking test methods include:
[0139] The unlocking test parameters include the contact area value. The preset mapping relationship includes the third mapping relationship. The driving parameters include the second sliding distance value.
[0140] S13. Obtain multiple different contact area values.
[0141] S23. Obtain multiple second sliding distance values that correspond one-to-one with multiple contact area values according to the third mapping relationship.
[0142] S33. Drive the bearing support 120 to move along the third direction Z according to multiple second sliding distance values, so that the orthogonal projection area of the unlocking module 130 on the bearing support 120 is adjustable, so that the pressing area of the unlocking member 1312 against the unlocking area 200 reaches the contact area value.
[0143] Thus, by adjusting at least one of the unlocking module 130 and the support 120, the contact area of the unlocking module 130 on the unlocking area 200 can be adjusted. With the unlocking area 200 arranged in a square and the unlocking module 130 arranged in a circle, the position of the unlocking module 130 in the second direction Y and / or the third direction Z can be adjusted. This allows the unlocking module 130 to be in different positions within the unlocking area 200. For example, if the unlocking module 130 is within the square area of the unlocking area 200, the contact area value can be 100% (i.e., the contact area of the unlocking module 130 occupies the entire area of the unlocking module 130; a contact area value of 100% means the unlocking module 130 is completely within the unlocking area 200). Alternatively, if the unlocking module 130 is on the edge of the square area of the unlocking area 200, the contact area value can be 90%, 80%, etc. Similarly, when the unlocking module 130 is outside the square area of the unlocking area 200, the contact area value can be 0%. Based on this, by selecting different contact area values, it is possible to determine the unlocking performance of the unlocking module 130 and the unlocking area 200 under various extreme conditions, which enriches the test scenarios and makes the detection reliability of smart door locks stronger.
[0144] Furthermore, in one example, the smart lock slides onto the support 120, allowing the position of the smart lock on the support 120 to be adjusted according to a second sliding distance value. On one hand, this facilitates adjusting the relative position between the unlocking area 200 and the unlocking component 1312, making it easier for the unlocking component 1312 to align with the unlocking area 200 for unlocking. On the other hand, unlike adjusting the position of the unlocking module 130, adjusting the position of the smart lock is simpler and easier to operate.
[0145] Furthermore, the support 120 may be equipped with a slider 120b and a groove 120a. The smart lock can be installed on the slider 120b, and the slider 120b is slidably positioned in the groove 120a, allowing the smart lock to slide relative to the groove 120a. Thus, the groove 120a and slider 120b provide movement limits for the sliding of the smart lock, improving its stability. The slider 120b also acts as an impact transition element when the groove 120a slides with the smart lock, thereby better protecting the smart lock.
[0146] Furthermore, in conjunction with any embodiment of the above-described button unlocking component and fingerprint unlocking component, at least one of the unlocking module 130 or at least a portion of the support 120 is inclined. In one example, the unlocking module 130 is inclined relative to the first direction X on the support component 110, so that the plane of the unlocking connector can be inclined relative to the unlocking area 200. In another example, at least a portion of the support 120 is inclined relative to the first direction X, such as by having a wedge-shaped platform, a boss, etc., installed on the support component 110 to cooperate with the support 120, or the support 120 itself has an inclined structure, so that the plane of the unlocking connector can be inclined relative to the unlocking area 200.
[0147] Understandably, when a user touches the unlocking area 200 to unlock, due to differences in the installation height of the smart lock, the user's pressure on the unlocking area 200 is not vertical, but rather at a certain angle. Therefore, tilting at least one of the unlocking module 130 and at least part of the support 120 better reflects actual unlocking scenarios, thereby improving the accuracy of unlocking tests.
[0148] Combination Figure 1 as well as Figure 10 In any embodiment of the unlocking module 130 described above, the unlocking module 130 includes an antenna unlocking component 132. The unlocking area 200 includes a region for fingerprint unlocking adapted to the antenna unlocking component 132; for ease of description, this region is referred to as the "antenna unlocking area". The antenna unlocking area may contain an antenna component capable of power feeding.
[0149] The antenna unlocking assembly 132 includes an electromagnetic unlocking component and a driving component. The electromagnetic unlocking component is used to power-unlock the antenna unlocking area. The driving component is used to drive the electromagnetic unlocking component to extend and retract along a first direction X according to driving parameters, such that the relative distance between the electromagnetic unlocking component and the antenna unlocking area reaches the unlocking test parameters.
[0150] The electromagnetic unlocking device can be, but is not limited to, electronic devices, card readers, etc. The antenna assembly in the antenna unlocking area can be, but is not limited to, Bluetooth antennas, NFC antennas, etc., without further restrictions. In addition, the drive assembly can be, but is not limited to, electrically controlled components such as electric cylinder assemblies and adjustable stroke cylinder assemblies 1311, or non-electrically controlled components such as manually movable guide rail assemblies.
[0151] Specifically, the unlocking test methods include:
[0152] The unlock test parameters include the communication distance value. The preset mapping relationship includes the fourth mapping relationship. The driving parameter can be the movement distance value.
[0153] S14. Obtain multiple different communication distance values.
[0154] S24. Obtain multiple movement distance values corresponding to multiple communication distance values according to the fourth mapping relationship.
[0155] S34. The driving component is driven according to multiple moving distance values to drive the electromagnetic unlocking component to move telescopically along the first direction X, so that the relative distance between the electromagnetic unlocking component and the antenna unlocking area reaches the communication distance value.
[0156] Understandably, the antenna unlocking area of a smart lock is equipped with an antenna component that can release electromagnetic signals when powered. When it encounters an electromagnetic unlocking device, it receives a response signal, which the smart lock can then receive to unlock itself. Generally, antenna components have limited radiation range due to bandwidth and power supply voltage limitations. Therefore, a driving component can be used to drive the electromagnetic unlocking device according to driving parameters, allowing adjustment of the relative distance between the electromagnetic unlocking device and the antenna unlocking area. This enables the detection of the unlocking performance of the smart lock's antenna unlocking area at different communication distances, enriching the unlocking scenarios and improving the reliability of smart lock detection.
[0157] In some embodiments, the driving assembly includes a third cylinder assembly 1311 and a sliding assembly. The third cylinder assembly 1311 is drively connected to the electromagnetic unlocking member and is used to drive the electromagnetic unlocking member to extend and retract along a first direction X. The sliding assembly extends along the first direction X, and the third cylinder assembly 1311 is slidably disposed on the sliding assembly, so that the relative distance between the third cylinder assembly 1311 and the antenna unlocking area is adjustable, thereby allowing the third cylinder assembly 1311 to drive the electromagnetic unlocking member to adjust the relative distance between the electromagnetic unlocking member and the antenna unlocking area.
[0158] Understandably, the faster transmission speed of the third cylinder assembly 1311 facilitates improved unlocking efficiency of the electromagnetic unlocking component in unlocking the antenna unlocking area, thereby enhancing unlocking detection efficiency. Furthermore, unlike third cylinder assemblies 1311 with adjustable stroke, this design uses a sliding component to slide the third cylinder assembly 1311, making the relative distance between the electromagnetic unlocking component and the antenna unlocking area adjustable. This allows the relative distance between the electromagnetic unlocking component and the antenna unlocking area to reach the communication distance value, eliminating the need for precise control via an additional limit switch, thus reducing costs and simplifying operation.
[0159] In one embodiment, the unlocking test method further includes: obtaining the lock type of the smart lock, obtaining a preset unlocking range based on the lock type, and obtaining multiple different unlocking test parameters based on the preset unlocking range.
[0160] Understandably, most smart locks have a limited unlocking range. By pre-determining the type of smart lock, one can obtain its preset unlocking range, such as the pressure resistance of the buttons and the distance for electromagnetic unlocking. In this way, obtaining multiple unlocking test parameters within this preset unlocking area (around 200 units) helps improve the reliability of data testing.
[0161] In another embodiment, multiple different unlocking test parameters exhibit a gradual changing trend. This creates gradually varying test parameters, which improves the reliability of the test results.
[0162] The data processing module 140 in the above embodiments may store a program, which, when executed, is used to implement the unlocking test method described above.
[0163] This application may take the form of a computer program product implemented on one or more computer-readable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) containing program code. Computer-readable storage media include permanent and non-permanent, removable and non-removable media, and information storage can be implemented using any method or technology. Information may be computer-readable instructions, data structures, program modules, or other data. Examples of computer-readable storage media include, but are not limited to: phase-change memory (PRAM), static random access memory (SRAM), dynamic random access memory (DRAM), other types of random access memory (RAM), read-only memory (ROM), electrically erasable programmable read-only memory (EEPROM), flash memory or other memory technologies, CD-ROM, digital versatile optical disc (DVD) or other optical storage, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other non-transfer medium that can be used to store information accessible by a computing device.
[0164] Furthermore, the data processing module 140 can be of various types, such as an MCU, and the communication connection between the data processing module 140 and the solenoid valve assembly 1313 in the above embodiment can be a wired electrical connection achieved through a combination of relays and wires, or a wireless communication connection achieved through Bluetooth, WIFI, etc., without too many restrictions.
[0165] In the description of this application, it should be understood that if terms such as "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential" appear, these terms indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this application.
[0166] Furthermore, where the terms "first" and "second" appear, these terms are for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined with "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this application, where the term "multiple" appears, "multiple" means at least two, such as two, three, etc., unless otherwise explicitly specified.
[0167] In this application, unless otherwise expressly specified and limited, the terms "installation," "connection," "joining," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms in this application based on the specific circumstances.
[0168] In this application, unless otherwise expressly specified and limited, the use of descriptions such as "above" or "below" the second feature indicates that the first and second features are in direct contact or indirect contact via an intermediate medium. Furthermore, "above," "on top of," and "over" the second feature can mean that the first feature is directly above or diagonally above the second feature, or simply that the first feature is at a higher horizontal level than the second feature. Similarly, "below," "below," and "under" the second feature can mean that the first feature is directly below or diagonally below the second feature, or simply that the first feature is at a lower horizontal level than the second feature.
[0169] It should be noted that if an element is referred to as being "fixed to" or "set on" another element, it can be directly on the other element or there may be an intervening element. If an element is considered to be "connected to" another element, it can be directly connected to the other element or there may be an intervening element. If so, the terms "vertical," "horizontal," "upper," "lower," "left," "right," and similar expressions used in this application are for illustrative purposes only and do not represent the only possible implementation.
[0170] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.
[0171] The embodiments described above are merely illustrative of several implementation methods of this application, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the patent application. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this application, and these all fall within the protection scope of this application. Therefore, the protection scope of this patent application should be determined by the appended claims.
Claims
1. An unlocking test system for testing the unlocking performance of a smart door lock, characterized in that, The unlocking test system includes: Support components; A support bracket is connected to the support assembly; the support bracket is used to install a smart door lock. An unlocking module is movably connected to the support component, and the unlocking module is capable of telescopic movement relative to the support component along a first direction; The data processing module is used to obtain the driving parameters that correspond one-to-one with the unlocking test parameters in the preset mapping relationship; wherein, the unlocking module is used to unlock the unlocking area of the smart door lock according to the driving parameters.
2. The unlocking test system according to claim 1, characterized in that, The unlocking module includes a pressure unlocking component, which includes a cylinder assembly and an unlocking element. The cylinder assembly is connected to the unlocking element and is used to drive the unlocking element to extend and retract along the first direction, so that the unlocking element presses against the unlocking area to unlock.
3. The unlocking test system according to claim 2, characterized in that, The unlocking module also includes a solenoid valve assembly, which is connected to the cylinder assembly in a one-to-one correspondence. The solenoid valve assembly is communicatively connected to the data processing module, and is used to receive the driving parameters to adjust the airflow of the cylinder assembly.
4. The unlocking test system according to claim 3, characterized in that, The unlocking component includes multiple button connectors, and the unlocking area includes multiple unlocking buttons; each of the multiple button connectors corresponds to one of the multiple unlocking buttons. The cylinder assembly includes multiple first cylinder assemblies, which are connected to the multiple button connectors in a transmission manner. The solenoid valve assembly includes a first solenoid valve; the first solenoid valve is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters.
5. The unlocking test system according to claim 3, characterized in that, The unlocking component includes a flexible fingerprint connector; the unlocking area includes a fingerprint unlocking area; the cylinder assembly includes a second cylinder assembly, which is operatively connected to the flexible fingerprint connector and is used to drive the flexible fingerprint connector to extend and retract along the first direction, so that the flexible fingerprint connector unlocks the fingerprint unlocking area; the solenoid valve assembly includes a second solenoid valve, which is connected to the second cylinder assembly and is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters.
6. The unlocking test system according to claim 2, characterized in that, The unlocking module is movably connected to the support component, and the unlocking module is movable relative to the support component in a second direction, so that the orthogonal projection area of the unlocking member on the unlocking area is adjustable, and the pressing area of the unlocking member against the unlocking area is adjustable; The second direction is perpendicular to the first direction; And / or, the support bracket is movably connected to the smart lock so that the smart lock can move upward relative to the support bracket along a third direction, so that the orthographic projection area of the unlocking module on the unlocking area is adjustable, and the pressing area of the unlocking member against the unlocking area is adjustable; The third direction is set perpendicular to the first direction.
7. The unlocking test system according to claim 1, characterized in that, The unlocking module is tilted relative to the first direction; And / or, at least a portion of the load-bearing supports are inclined relative to the first direction.
8. The unlocking test system according to claim 1, characterized in that, The unlocking module includes an antenna unlocking component, which includes an electromagnetic unlocking element and a driving component. The unlocking area includes an antenna unlocking area. The electromagnetic unlocking element is used to power-unlock the antenna unlocking area. The driving component is used to drive the electromagnetic unlocking element to extend and retract along the first direction; wherein, the driving component is communicatively connected to the data processing module so that the driving component receives the driving parameters and adjusts the relative distance between the electromagnetic unlocking element and the antenna unlocking area according to the driving parameters.
9. The unlocking test system according to claim 8, characterized in that, The driving assembly includes a third cylinder assembly and a sliding assembly; the third cylinder assembly is connected to the electromagnetic unlocking component and is used to drive the electromagnetic unlocking component to extend and retract along the first direction; the sliding assembly extends along the first direction, and the third cylinder assembly is slidably disposed on the sliding assembly, so that the relative distance between the third cylinder assembly and the antenna unlocking area is adjustable, thereby making the relative distance between the electromagnetic unlocking component and the antenna unlocking area adjustable.
10. An unlocking test method based on the unlocking test system as described in any one of claims 1 to 9, characterized in that, The unlocking test method includes: Obtain multiple different unlock test parameters; Based on the preset mapping relationship, obtain multiple driving parameters that correspond one-to-one with the multiple unlock test parameters; The unlocking module is driven multiple times according to the multiple driving parameters, so that the unlocking module unlocks the unlocking area; Determine whether the smart lock has been successfully unlocked. If it has been successfully unlocked, the smart lock is considered to be in a normal unlocking state; otherwise, the smart lock is considered to be in an abnormal unlocking state.
11. The unlocking test method according to claim 10, characterized in that, The unlocking test method further includes: obtaining the lock type of the smart lock; obtaining a preset unlocking range based on the lock type; and obtaining the multiple different unlocking test parameters based on the preset unlocking range. And / or, the multiple different unlocking test parameters show a gradual changing trend.
12. The unlocking test method according to claim 10, characterized in that, The unlocking module includes a cylinder assembly and an unlocking component; the cylinder assembly is connected and cooperates with the unlocking component, and the cylinder assembly is used to drive the unlocking component to extend and retract along the first direction, so that the unlocking component presses against the unlocking area to unlock; The unlocking test method includes: The unlocking test parameters include at least one of the contact pressure value between the unlocking component and the unlocking area and the contact area value between the unlocking component and the unlocking area.
13. The unlocking test method according to claim 12, characterized in that, The unlocking module also includes a solenoid valve assembly, which is connected to the cylinder assembly in a one-to-one correspondence. The solenoid valve assembly is communicatively connected to the data processing module, and the solenoid valve assembly is used to receive the driving parameters to adjust the air flow of the cylinder assembly. The unlocking test method includes: The preset mapping relationship includes a first mapping relationship; the driving parameters include the solenoid valve opening value; Obtain multiple different unlock test parameters; Based on the first mapping relationship, obtain multiple solenoid valve opening values that correspond one-to-one with the multiple unlocking test parameters; The solenoid valve assembly is opened to the solenoid valve opening value so that the cylinder assembly is pressed against the unlocking area with a pressure that reaches the unlocking test parameter.
14. The unlocking test method according to claim 13, characterized in that, The unlocking component includes multiple button connectors, and the unlocking area includes multiple unlocking buttons; each of the multiple button connectors corresponds to one of the multiple unlocking buttons. The cylinder assembly includes multiple first cylinder assemblies, which are connected to the multiple button connectors in a transmission manner. The solenoid valve assembly includes multiple first solenoid valves; the first solenoid valves are connected in communication with the first cylinder assembly and are communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters. The unlocking test method includes: The unlocking test parameters include the contact pressure value; the first mapping relationship includes a first sub-mapping relationship; the driving parameters include a first opening value; Obtain the unlocking order, and obtain multiple different contact pressure values; Based on the first sub-mapping relationship, obtain a plurality of first opening values that correspond one-to-one with the plurality of contact pressure values; According to the unlocking order, multiple first solenoid valves are driven sequentially to open to a first opening value, so that multiple first cylinder assemblies sequentially drive multiple button connectors to press against the corresponding unlocking button to unlock, and the pressure of the button connector against the unlocking area reaches the contact pressure value.
15. The unlocking test method according to claim 13, characterized in that, The unlocking component includes a flexible fingerprint connector; the unlocking area includes a fingerprint unlocking area; the cylinder assembly includes a second cylinder assembly, the solenoid valve assembly includes a second solenoid valve, the second cylinder assembly is pulsatorically connected to the flexible fingerprint connector, the second cylinder assembly is used to drive the flexible fingerprint connector to extend and retract along the first direction, so that the flexible fingerprint connector unlocks the fingerprint unlocking area; the solenoid valve assembly includes a second solenoid valve, the second solenoid valve is connected to the second cylinder assembly, the second solenoid valve is communicatively connected to the data processing module to receive the driving parameters and adjust the opening degree according to the driving parameters; the unlocking test method includes: The unlocking test parameters include the contact area value; the first mapping relationship includes a second sub-mapping relationship; the solenoid valve opening value includes a second opening value; Obtain multiple different contact area values; According to the second sub-mapping relationship, obtain a plurality of second opening values that correspond one-to-one with the plurality of contact area values; Open the second solenoid valve to the second opening value so that the fingerprint connector presses against the fingerprint unlocking area to reach the contact area value.
16. The unlocking test method according to claim 12, characterized in that, The unlocking module is movably connected to the support component, and the unlocking module is movable relative to the support component in a second direction; The second direction is perpendicular to the first direction; the unlocking test method includes: The unlocking test parameters include the contact area value; the preset mapping relationship includes a second mapping relationship; the driving parameters include a first sliding distance value; Obtain multiple different contact area values; According to the second mapping relationship, a plurality of first sliding distance values are obtained that correspond one-to-one with the plurality of contact area values; The unlocking module is driven to move along the second direction according to a plurality of first sliding distance values, so that the orthogonal projection area of the unlocking module on the bearing support is adjustable, and the pressing area of the unlocking member against the unlocking area reaches the contact area value. And / or, The support bracket is movably connected to the smart lock, so that the smart lock can move upward relative to the support bracket along a third direction; the third direction is perpendicular to the first direction. The unlocking test method includes: The unlocking test parameters include the contact area value; the preset mapping relationship includes a third mapping relationship; the driving parameters include a second sliding distance value; Obtain multiple different contact area values; According to the third mapping relationship, obtain a plurality of second sliding distance values that correspond one-to-one with the plurality of contact area values; The support is driven to move along the third direction according to multiple second sliding distance values, so that the orthogonal projection area of the unlocking module on the support is adjustable, and the pressing area of the unlocking member against the unlocking area reaches the contact area value.
17. The unlocking test method according to claim 10, characterized in that, The unlocking module includes an antenna unlocking component, which includes an electromagnetic unlocking element and a driving component, and the unlocking area includes an antenna unlocking area. The electromagnetic unlocking component is used to power-unlock the antenna unlocking area; The unlocking test method includes: The unlocking test parameters include a communication distance value; the preset mapping relationship includes a fourth mapping relationship; the driving parameters include a movement distance value; Obtain multiple different communication distance values; According to the fourth mapping relationship, obtain multiple movement distance values corresponding to the multiple communication distance values; The driving component is driven according to a plurality of the moving distance values to drive the electromagnetic unlocking component to extend and retract along the first direction, so that the relative distance between the electromagnetic unlocking component and the antenna unlocking area reaches the communication distance value.