Abstract: In one embodiment, a test system comprises: a network access point simulation component, a local control component, and a reference component. The network access point simulation component is configured to simulate communication network access point operations comprising test interactions with user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated are variable. The local control component is configured to direct the network access point simulation component and to control the test interactions with the user equipment. The local control component comprises a test executive operable to direct simulation of communication network operations and the test interactions in accordance with information received from the remote control components. The reference component is operable to communicatively couple with the network access point simulation component similar to the user equipment and validate the test interactions.

Abstract: In one embodiment, a test system comprises a first interface for communicating with remote devices; a second interface for communicating with local devices; a memory for storing information, including information received from the first interface and second interface; a processor for automatically configuring test system components in accordance with the information stored in the memory. The test system components comprise a network access point simulation component and a local control component. The network access point simulation component is configured to simulate communication network access point operations comprising test interactions with user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated can be variable. The local control component is configured to direct the network access point simulation component and to control the test interactions with the user equipment.

Abstract: In one embodiment, a test system comprises: a network access point simulation component configured to simulate network access point operations and to simulate test interactions with user equipment, and a local control component configured to direct the network access point simulation component and to control test interactions with the user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated are variable. In one exemplary implementation, the local control component comprises a test executive operable to direct simulation of communication network operations and the test interactions in accordance with information received from the remote control components. The network access point simulation component and local control component are portable.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller coupled to a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The enclosure comprises a plurality of components, wherein the processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic. The plurality of components comprises: (a) a robotic arm comprising a stylus affixed thereto; and (b) a platform comprising a device holder affixed thereto, wherein the smart device is inserted into the device holder; and (c) a wireless access point. The processor is further configured to: (a) control the smart device to activate wireless mode; (b) receive wireless signals from the wireless access point using the smart device; (c) retrieve wireless scan results from the smart device; and (d) analyze the wireless scan results.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller coupled to and operable to stress a smart device in an enclosure, wherein the enclosure comprises a plurality of components, and wherein the system controller comprises: (a) a memory comprising test logic; and (b) a processor configured to automatically control the plurality of components and test the smart device in accordance with the test logic. Further, the plurality of components comprises: (a) a robotic arm comprising a stylus affixed thereto, wherein the stylus is operable to manipulate the smart device; and (b) a platform comprising a device holder affixed thereto, wherein the device holder is operable to receive the smart device, and wherein the platform and the robotic arm are robotically controlled to move by the processor.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller operable to be coupled with a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The system also comprises the enclosure, wherein the enclosure comprises a plurality of components, the plurality of components comprising: (i) a robotic arm comprising a stylus, wherein the stylus is operable to manipulate the smart device to simulate human interaction therewith; and (ii) a platform comprising a device holder, wherein the device holder is operable to receive a smart device inserted there into. The processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic.

Abstract: Cloud-based management of cell-based test systems is described. For example, at a server that is communicatively coupled to a cell-based test system via a network (that is, in the cloud), a test case from a test case library is selected and accessed. The test case is selected according to the type of user equipment to be tested at the cell-based test system. The test case is sent from the server over the network to the cell-based test system. The cell-based test system can automatically perform the test case on the user equipment. Results from performing the test case on the user equipment are then stored on the cloud; that is, the test results are received at the server from the cell-based test system over the network and stored at the server. A report based on the test results can be prepared and stored on the server (in the cloud).

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller coupled to a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The enclosure comprises a plurality of components, wherein the processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic. The plurality of components comprises: (a) a robotic arm comprising a stylus affixed thereto; and (b) a platform comprising a device holder affixed thereto, wherein the smart device is inserted into the device holder; and (c) a wireless access point. The processor is further configured to: (a) control the smart device to activate wireless mode; (b) receive wireless signals from the wireless access point using the smart device; (c) retrieve wireless scan results from the smart device; and (d) analyze the wireless scan results.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller coupled to a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The enclosure comprises a plurality of components, wherein the processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic. The plurality of components comprises: (a) a robotic arm comprising a stylus affixed thereto; and (b) a platform comprising a device holder affixed thereto, wherein the smart device is inserted into the device holder; and (c) a wireless access point. The processor is further configured to: (a) control the smart device to activate wireless mode; (b) receive wireless signals from the wireless access point using the smart device; (c) retrieve wireless scan results from the smart device; and (d) analyze the wireless scan results.

Abstract: To test user equipment at a cell-based test system, a type of user equipment to be tested is determined. A device profile for the type of the user equipment to be tested is accessed. The device profile includes, for example, a test script that can be used to control the user equipment during the testing. A test of the user equipment is performed at the cell-based test system. During the test, the user equipment is controlled according to the device profile in response to the software executing on a computer system.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller operable to be coupled with a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The system also comprises the enclosure, wherein the enclosure comprises a plurality of components, the plurality of components comprising: (i) a robotic arm comprising a stylus, wherein the stylus is operable to manipulate the smart device to simulate human interaction therewith; and (ii) a platform comprising a device holder, wherein the device holder is operable to receive a smart device inserted there into. The processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic.

Abstract: An automated test system for testing smart devices is presented. The system includes a system controller coupled to a smart device, wherein the system controller includes a memory with test logic and a processor. The system also includes an enclosure with a plurality of components. The plurality of components include (a) a robotic arm with a stylus, wherein the stylus is operable to manipulate the smart device to simulate human interaction therewith; (b) a platform with a device holder, wherein the device holder is operable to hold a smart device inserted therein; (c) an audio capture and generator device; and (d) a microphone. The processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller operable to be coupled with a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The system also comprises the enclosure, wherein the enclosure comprises a plurality of components, the plurality of components comprising: (i) a robotic arm comprising a stylus, wherein the stylus is operable to manipulate the smart device to simulate human interaction therewith; and (ii) a platform comprising a device holder, wherein the device holder is operable to receive a smart device inserted there into. The processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic.

Abstract: Cloud-based management of cell-based test systems is described. For example, at a server that is communicatively coupled to a cell-based test system via a network (that is, in the cloud), a test case from a test case library is selected and accessed. The test case is selected according to the type of user equipment to be tested at the cell-based test system. The test case is sent from the server over the network to the cell-based test system. The cell-based test system can automatically perform the test case on the user equipment. Results from performing the test case on the user equipment are then stored on the cloud; that is, the test results are received at the server from the cell-based test system over the network and stored at the server. A report based on the test results can be prepared and stored on the server (in the cloud).

Abstract: In one embodiment, a test system comprises: a network access point simulation component, a local control component, and a reference component. The network access point simulation component is configured to simulate communication network access point operations comprising test interactions with user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated are variable. The local control component is configured to direct the network access point simulation component and to control the test interactions with the user equipment. The local control component comprises a test executive operable to direct simulation of communication network operations and the test interactions in accordance with information received from the remote control components. The reference component is operable to communicatively couple with the network access point simulation component similar to the user equipment and validate the test interactions.

Abstract: To test user equipment at a cell-based test system, a type of user equipment to be tested is determined. A device profile for the type of the user equipment to be tested is accessed. The device profile includes, for example, a test script that can be used to control the user equipment during the testing. A test of the user equipment is performed at the cell-based test system. During the test, the user equipment is controlled according to the device profile in response to the software executing on a computer system.

Abstract: In one embodiment, a test system comprises a first interface for communicating with remote devices; a second interface for communicating with local devices; a memory for storing information, including information received from the first interface and second interface; a processor for automatically configuring test system components in accordance with the information stored in the memory. The test system components comprise a network access point simulation component and a local control component. The network access point simulation component is configured to simulate communication network access point operations comprising test interactions with user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated can be variable. The local control component is configured to direct the network access point simulation component and to control the test interactions with the user equipment.

Abstract: In one embodiment, a test system comprises: a network access point simulation component configured to simulate network access point operations and to simulate test interactions with user equipment, and a local control component configured to direct the network access point simulation component and to control test interactions with the user equipment. The number of devices under test included in the user equipment and distinct network access points that are coincidentally simulated are variable. In one exemplary implementation, the local control component comprises a test executive operable to direct simulation of communication network operations and the test interactions in accordance with information received from the remote control components. The network access point simulation component and local control component are portable.

Abstract: A method of validating the end to end performance of a mobile device including performance of applications, related services, and the mobile device by automating the conditions of the End User environment. The method is accomplished by leveraging stress models and applying these to automate the stressing of applications, their related services, while the device performance is being monitored by varying the emulated radio network and packet data network conditions.

Abstract: An automatic system level testing (ASLT) system for testing smart devices is disclosed. The system comprises a system controller operable to be coupled with a smart device in an enclosure, wherein the system controller comprises a memory comprising test logic and a processor. The system also comprises the enclosure, wherein the enclosure comprises a plurality of components, the plurality of components comprising: (i) a robotic arm comprising a stylus, wherein the stylus is operable to manipulate the smart device to simulate human interaction therewith; and (ii) a platform comprising a device holder, wherein the device holder is operable to receive a smart device inserted there into. The processor is configured to automatically control the smart device and the plurality of components in accordance with the test logic.