A movable body control system (SYS) includes a movable body (1) that is movable in a predetermined area (TA) in which a wireless communication network (NW) is built; a control apparatus (6) for controlling the movable body through the wireless communication network; and a measurement apparatus (3) for measuring a communication quality of the wireless communication network in the predetermined area, the control apparatus includes a generation unit (613) for generating, as a target moving route (TGT) for the movable body, a first route avoiding a low quality area (DA1) in which the communication quality does not reach a desired quality in the predetermined area, based on a measured result by the measurement apparatus; and a control unit (614) for controlling the movable body so that the movable body moves along the target moving route.

A technique is directed to methods and systems of virtual site inspections. In some embodiments, a network operator navigates a drone which captures image data of equipment and layout of a site. The image data is processed and used to generate a 3D model of the site. A network operator virtually installs new equipment in the virtual representation of the site, and presents the 3D model of the site, with the new equipment in the proposed location, to a permitting authority. The permitting authority can review the 3D model of the new equipment at the site and approve or deny authorization for the network operator to physically install the equipment at the site. After the new equipment is installed, a network operator can capture image data of the installed equipment at the site to prove to the permitting authority that the equipment was installed at the site according to regulation.

A technique is directed to methods and systems of virtual site inspections. In some embodiments, a network operator navigates a drone which captures image data of equipment and layout of a site. The image data is processed and used to generate a 3D model of the site. A network operator virtually installs new equipment in the virtual representation of the site, and presents the 3D model of the site, with the new equipment in the proposed location, to a permitting authority. The permitting authority can review the 3D model of the new equipment at the site and approve or deny authorization for the network operator to physically install the equipment at the site. After the new equipment is installed, a network operator can capture image data of the installed equipment at the site to prove to the permitting authority that the equipment was installed at the site according to regulation.

Methods and systems are provided for deploying a cellular communication network, including basestation systems. A basestation system may include a plurality of femtocells including at least a first femtocell and a second femtocell, with the first femtocell being operable to support an operation in a coverage area corresponding to the second femtocell. A first transmission within the coverage area from the first femtocell may be coordinated with a second transmission within the coverage area from the second femtocell. The plurality of femtocells may further include a third femtocell, and a first reception by the first femtocell may be coordinated with a second reception by the third femtocell. The transmissions and/or receptions may be coordinated in one or more of time, power, and frequency.

Methods and systems are provided for deploying a cellular communication network, including basestation systems. A basestation system may include a plurality of femtocells including at least a first femtocell and a second femtocell, with the first femtocell being operable to support an operation in a coverage area corresponding to the second femtocell. A first transmission within the coverage area from the first femtocell may be coordinated with a second transmission within the coverage area from the second femtocell. The plurality of femtocells may further include a third femtocell, and a first reception by the first femtocell may be coordinated with a second reception by the third femtocell. The transmissions and/or receptions may be coordinated in one or more of time, power, and frequency.

The present disclosure describes a method, an apparatus, and a computer readable medium for a multilayer transmission in a wireless network. For example, the method may include generating a group of binary data bits for resources of each layer of a plurality of layers, mapping the group of binary data bits of each layer of the plurality of layers to respective code words in a signal constellation, combining the code words, and transmitting the combined code word to receiver in the wireless network. As such, the multilayer transmission in a wireless network is achieved.

The present disclosure describes a method, an apparatus, and a computer readable medium for a multilayer transmission in a wireless network. For example, the method may include generating a group of binary data bits for resources of each layer of a plurality of layers, mapping the group of binary data bits of each layer of the plurality of layers to respective code words in a signal constellation, combining the code words, and transmitting the combined code word to receiver in the wireless network. As such, the multilayer transmission in a wireless network is achieved.

The present disclosure relates to a spectrum management apparatus and method, a wireless network management apparatus and method, and a medium. According to one embodiment, an electronic apparatus for spectrum management comprises a processing circuit configured to generate measurement configuration information and to conduct control to send the measurement configuration information to one or more wireless network management apparatuses. The measurement configuration information comprises a measurement mode, and the measurement mode comprises at least one of the following modes: the wireless network management apparatus managed by the electronic apparatus performing measurement, and one or more specific nodes of the wireless network management apparatus performing measurement.

Facilitating implementation of communication network deployment through network planning in advanced networks (e.g., 5G, 6G, and beyond) is provided herein. Operations of a system can include, configuring a first deployment scenario for first network equipment and a second deployment scenario for second network equipment. The first deployment scenario is selected from a group of first deployment scenarios and can include a first parameter. The second deployment scenario is selected from a group of second deployment scenarios and can include a second parameter. The configuring can include determining that a sum of the first parameter and the second parameter satisfies a function of a defined parameter level. The operations also can include facilitating a first enactment of the first deployment scenario for the first network equipment and a second enactment of the second deployment scenario for the second network equipment.

Facilitating implementation of communication network deployment through network planning in advanced networks (e.g., 5G, 6G, and beyond) is provided herein. Operations of a system can include, configuring a first deployment scenario for first network equipment and a second deployment scenario for second network equipment. The first deployment scenario is selected from a group of first deployment scenarios and can include a first parameter. The second deployment scenario is selected from a group of second deployment scenarios and can include a second parameter. The configuring can include determining that a sum of the first parameter and the second parameter satisfies a function of a defined parameter level. The operations also can include facilitating a first enactment of the first deployment scenario for the first network equipment and a second enactment of the second deployment scenario for the second network equipment.