Personal medical devices

Radio waves may affect the operation of cardiac pacemakers and other implanted equipment. If a minimum distance of 15 cm is kept between the antenna and the pacemaker, the risk of interference is limited. If you have any reason to suspect that interference is taking place, immediately move away from the antenna. Contact your cardiologist for more infor- mation.

For other medical devices, please consult the manufacturer of the de- vice.

Potentially explosive atmospheres

Do not use your product in an area where a potentially explosive atmos- phere exists.

Power supply

Ensure that your AC power outlet is adequately grounded, that it is situated near the FWT and it is easily accessible.

Connect the power supply cord only to the AC power outlet that meets the specifications marked on the FWT power supply.

Never alter the AC power cord or plug. If necessary have the correct outlet installed by a qualified electrician or call your service provider for assistance.

To reduce risk of damage to the electric cord, remove it from the outlet by holding onto the AC adapter rather than the cord.

Make sure the cord is positioned so that it will not be stepped on, tripped over or otherwise subjected to damage or stress.

Children

DO NOT ALLOW CHILDREN TO PLAY WITH YOUR FWT SINCE IT CONTAINS SMALL PARTS THAT COULD BECOME DETACHED AND CREATE A CHOKING HAZARD.

Fixed Wireless Terminal: G32 & G36

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Ericsson G32, G36 manual Personal medical devices, Potentially explosive atmospheres, Power supply, Children

G32, G36 specifications

Ericsson has long been a leader in the telecommunications industry, providing innovative solutions that cater to the evolving needs of network operators around the globe. Among its impressive lineup, the Ericsson G36 and G32 models stand out as remarkable technologies, designed to enhance connectivity, efficiency, and performance in various environments.

The Ericsson G36 is positioned as a high-capacity macro radio, specifically engineered for dense urban areas and environments with significant traffic demands. One of the main features of the G36 is its advanced Massive MIMO (Multiple Input Multiple Output) technology. This allows the system to support multiple data streams simultaneously, improving overall throughput and network reliability. By maximizing spectral efficiency, Massive MIMO boosts capacity without requiring additional spectrum resources, which is a critical advantage in today’s data-driven landscape.

The G36 is also equipped with dynamic beamforming capabilities. This technology enhances signal quality by directing beams towards users, reducing interference, and improving coverage. With its ability to adapt to changing traffic patterns, the G36 ensures that users experience seamless connectivity, even during peak times. Supporting both 4G LTE and 5G NR, the G36 is a future-ready solution that allows operators to transition smoothly to next-generation networks.

On the other hand, the Ericsson G32 offers a more compact solution without compromising on performance. Designed for rural areas or small cell deployments, the G32 integrates advanced features in a smaller footprint. It is optimized for indoor and outdoor applications, making it versatile and suitable for a range of deployment scenarios. The G32 supports Ericsson's latest software and network functions, allowing operators to leverage features like network slicing and enhanced edge computing capabilities.

Another notable characteristic of the G32 is its energy efficiency. Built with sustainability in mind, this model minimizes power consumption while maintaining effective performance levels, aligning with industry goals for greener network solutions. This technology not only helps in reducing operational costs but also contributes to the overall reduction of carbon footprints.

Both the Ericsson G36 and G32 showcase the company's commitment to innovation, providing robust solutions that enable operators to meet the demands of modern telecommunications. With their advanced features, energy-efficient designs, and adaptability to various deployment scenarios, these models are set to play crucial roles in the evolution of connectivity worldwide.