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GL-DY017
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8517710000
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5G Patch Antenna | |
GL-DY017 | |
Electrical Index | |
Frequency-MHz | 698-960/1710-3800 |
VSWR | <1.5 |
Nominal Impedance-Ω | 50 |
Polarization | Vertical |
Gain-dBi | 2.5 |
Mechanical Index | |
Cable Length | RG174,2.5m |
Connector | SMA male |
Antenna Dimension-mm | 115.6*21.7*5.8 |
Installation Way | 3M sticky |
Vibration | 10 to 55Hz with 1.5mm amplitude 2hours |
Environmentally Friendly | ROHS Compliant |
Temperature-℃ | -40~+85 |
Humidity-﹪ | 5~95 |
Patch antennas, also known as microstrip antennas, are a popular choice for wireless communication applications due to their compact size, low profile, and ease of integration. Here are some key features of patch antennas:
Compact Size: Patch antennas are known for their small size, making them suitable for applications where space is limited. Their compact form factor allows for easy integration into various devices and systems.
Low Profile: Patch antennas have a low profile, which means they are thin and do not protrude significantly from the surface they are mounted on. This makes them aesthetically pleasing and minimizes the risk of damage or interference.
Broadband Operation: Patch antennas can be designed to operate over a wide frequency range, making them versatile for different wireless communication standards and protocols. They can support multiple frequency bands or be tuned to specific frequencies.
Directional Radiation Pattern: Patch antennas typically have a directional radiation pattern, which means they emit and receive signals in a specific direction. This allows for better signal focusing, increased gain, and reduced interference from other directions.
High Gain: Patch antennas can achieve high gain, which refers to the ability to concentrate the signal in a specific direction. High gain antennas provide better signal strength, extended coverage, and improved signal quality.
Polarization Diversity: Patch antennas can be designed to support different polarization types, such as linear or circular polarization. This allows for compatibility with various communication systems and helps mitigate signal degradation caused by polarization mismatch.
Wide Beamwidth: Patch antennas can have a wide beamwidth, which means they can cover a larger area with their radiation pattern. This is beneficial for applications where a broader coverage area is required.
Low Cost: Patch antennas are relatively inexpensive to manufacture compared to other types of antennas. Their simple design and use of printed circuit board (PCB) technology contribute to their cost-effectiveness.
Easy Integration: Patch antennas can be easily integrated into PCBs or other surfaces, making them suitable for mass production and high-volume applications. They can be mounted directly on a substrate or embedded within a device.
Customizable Design: Patch antennas can be customized to meet specific requirements, such as frequency range, gain, beamwidth, and polarization. This flexibility allows for optimization based on the application's needs.
These features make patch antennas a popular choice in wireless communication systems, including mobile devices, IoT devices, wireless routers, satellite communication, and many other applications where compact size, low profile, and reliable performance are essential.
5G Patch Antenna | |
GL-DY017 | |
Electrical Index | |
Frequency-MHz | 698-960/1710-3800 |
VSWR | <1.5 |
Nominal Impedance-Ω | 50 |
Polarization | Vertical |
Gain-dBi | 2.5 |
Mechanical Index | |
Cable Length | RG174,2.5m |
Connector | SMA male |
Antenna Dimension-mm | 115.6*21.7*5.8 |
Installation Way | 3M sticky |
Vibration | 10 to 55Hz with 1.5mm amplitude 2hours |
Environmentally Friendly | ROHS Compliant |
Temperature-℃ | -40~+85 |
Humidity-﹪ | 5~95 |
Patch antennas, also known as microstrip antennas, are a popular choice for wireless communication applications due to their compact size, low profile, and ease of integration. Here are some key features of patch antennas:
Compact Size: Patch antennas are known for their small size, making them suitable for applications where space is limited. Their compact form factor allows for easy integration into various devices and systems.
Low Profile: Patch antennas have a low profile, which means they are thin and do not protrude significantly from the surface they are mounted on. This makes them aesthetically pleasing and minimizes the risk of damage or interference.
Broadband Operation: Patch antennas can be designed to operate over a wide frequency range, making them versatile for different wireless communication standards and protocols. They can support multiple frequency bands or be tuned to specific frequencies.
Directional Radiation Pattern: Patch antennas typically have a directional radiation pattern, which means they emit and receive signals in a specific direction. This allows for better signal focusing, increased gain, and reduced interference from other directions.
High Gain: Patch antennas can achieve high gain, which refers to the ability to concentrate the signal in a specific direction. High gain antennas provide better signal strength, extended coverage, and improved signal quality.
Polarization Diversity: Patch antennas can be designed to support different polarization types, such as linear or circular polarization. This allows for compatibility with various communication systems and helps mitigate signal degradation caused by polarization mismatch.
Wide Beamwidth: Patch antennas can have a wide beamwidth, which means they can cover a larger area with their radiation pattern. This is beneficial for applications where a broader coverage area is required.
Low Cost: Patch antennas are relatively inexpensive to manufacture compared to other types of antennas. Their simple design and use of printed circuit board (PCB) technology contribute to their cost-effectiveness.
Easy Integration: Patch antennas can be easily integrated into PCBs or other surfaces, making them suitable for mass production and high-volume applications. They can be mounted directly on a substrate or embedded within a device.
Customizable Design: Patch antennas can be customized to meet specific requirements, such as frequency range, gain, beamwidth, and polarization. This flexibility allows for optimization based on the application's needs.
These features make patch antennas a popular choice in wireless communication systems, including mobile devices, IoT devices, wireless routers, satellite communication, and many other applications where compact size, low profile, and reliable performance are essential.
