Antenna manufacturers are finding new ways to accommodate the need for simultaneous voice, data, GPS and more.
The critical communications industry is evolving, and the era of traditional two-way voice being the only means of communication between a control room and a user in the field is over. Vehicles are being fitted with more technology, from onboard computers to equipment to fight crime and manage medical and fire situations.
These solutions are powered by the 4G LTE revolution, which is providing a high-speed wireless data stream from the network carriers alongside more secure, wireless local area networks.
However, such advances require innovation in many types of hardware, including antennas. This article explores the importance of using a combination mobile antenna to achieve best performance and utilisation on a public safety vehicle.
For many years, supplying the critical communications industry with mobile antennas was relatively straightforward. The customer selected a mobile radio, had a specific frequency designated for its use and simply sourced all the appropriate accessories, including mobile antennas tuned to suit.
This all changed with the need to transmit large packets of data wirelessly via cellular networks. The number of antennas required on a vehicle drastically increased to keep up with the data throughput, and this brought with it a number of challenges. Combination antennas have become more important and widespread as a way to tackle this growing challenge.
Modern vehicles have much smaller roof spaces, as well as styling that is dominated by a central light bar. A good example of this came with the discontinuation of the Crown Victoria vehicle by Ford in the USA in , after which many police forces switched to the Dodge Challenger as their preferred new patrol vehicle.
With the addition of a few antennas for conventional radio, space becomes increasingly restricted, making it difficult to install auxiliary antenna equipment — especially for those that have a large ground plane and need to be as elevated as possible.
Furthermore, there is a push for police vehicles to appear more stealthy and less like standard law enforcement vehicles. So fitting standard antenna products is not always an option.
More recently, the challenge has become even harder with vehicles such as the Ford Explorer, with its ribbed roof line, becoming increasingly popular. This has meant that only certain shapes will fit on the roof, bringing with it additional complications for antenna product design, especially if larger-footprint combination antennas are desired.
Some of the ways to get around the issue of restricted space include combining different-frequency antennas together in a single housing or developing a multiband antenna. These techniques have become more sophisticated and customers now expect that auxiliary antennas will very closely resemble the OEM car antenna.
This brings its own difficulties, as the antenna has to look aesthetically pleasing while maintaining a small and correct shape. With vehicles potentially fitted with cellular and Wi-Fi capable devices, as well as conventional radio, this expectation becomes a bit of a dilemma.
Furthermore, there is the potential to run into interference issues if the antennas are placed too close to one another. 700 MHz, a commonly used band in certain areas of the world, adds further complexity, as a standard ¼ wave at this frequency is approximately 10 cm in length. Disguising such an antenna is challenging.
In addition, as these antennas are used for mission-critical deployment, they must be good quality and correctly tuned before they are installed to ensure a reliable and high-performance connection is maintained at all times.
With the need to boost data rates so that users can send large files, multiple-input, multiple-output (MIMO) antennas have become increasingly necessary. This brings its own complexities as MIMO requires multiple, same-frequency antennas to operate simultaneously in the designated frequency band.
Given that MIMO antennas need to be spaced appropriately to avoid interference, and there is restricted roof space and tight budgets, antenna manufacturers are under pressure to come up with innovative designs while also meeting customers’ performance expectations.
This is even more challenging as LTE 700/800 MHz networks are rolled out, with potentially patchy coverage.
Public safety authorities worldwide are also looking at all possible ways to reduce costs and remain within shrinking budgets, while meeting expectations to have the latest technology. This has placed added pressure on component manufacturers to come up with cheaper, more cost-effective, more efficient and better designs.
Combining antennas into a single housing is one way of getting around this issue, as they reduce the cost and time for installation and can potentially help retain the resale value of the vehicle.
They also can futureproof the vehicle. For example, a combination antenna may have GPS, cellular or Wi-Fi capability even if the user currently does not need such functionality. However, given its ubiquity it is likely that such a user will adopt GPS, cellular and/or Wi-Fi within the next few years, in which case they will not need to add any further external equipment as it will be already installed.
Cutaway diagram of a Sharkee antenna.
It’s for these reasons that Panorama has invested heavily in the development of the MIMO Sharkee vehicle antenna unit. This shark fin-style, semi-covert unit accommodates up to six antennas in a single product, designed to fit within a vehicle’s ribbed roof line. With two wideband 700– MHz antennas offering the MIMO performance desired by the public safety industry, it covers all the standard cellular frequencies. Two dual-band 2.4 and 5.8 GHz Wi-Fi antennas offer MIMO capability for high-speed data transmission in and around the vehicle, and an active 26 dB GPS module means the vehicle’s location is known at all times when data is being transmitted. A whip placement enables the customer to adopt their VHF, UHF, dual-band or even tri-band antenna.
Antennas such as this address the transition between traditional conventional radio and advanced wireless technology, while meeting the key challenges and demands of the public safety industry in the 21st century.
Images courtesy Panorama Antennas and dealers
In the complex world of wireless communications, one component that plays a pivotal role yet remains underappreciated is the antenna combiner. This device, essential for managing multiple frequencies within limited spaces, ensures that high-quality transmission is maintained without the clutter of numerous antennas. Whether you’re a RF technician , or an hardware engineer overseeing large-scale communications infrastructure, understanding antenna combiners can significantly streamline your operations.
An antenna combiner is a device designed to consolidate signals from multiple antennas into a single output. This design enables the efficient management of multiple frequencies without requiring additional physical space for numerous antennas, thus optimizing both system performance and setup simplicity.
We will examine how antenna combiners work and why they are essential in many modern setups, without compromising transmission quality.
An antenna combiner is a device used to combine the signals from multiple antennas into a single output. It is commonly used in applications where multiple antennas are required to cover a larger area or to improve the signal strength and quality.
The design of an antenna combiner involves several key components:
1. Antennas: The combiner is designed to work with multiple antennas. Each antenna is designed to receive signals from a specific frequency range or direction.
2. Coaxial cables: Coaxial cables are used to connect each antenna to the combiner. These cables transmit the received signals from the antennas to the combiner unit.
3. Combiner unit: The combiner unit is the central component of the system. It receives the signals from each antenna and combines them into a single output. The combiner unit typically consists of filters, amplifiers, and a combining network.
– Filters: Filters are used to separate the signals received by each antenna based on their frequency range. This ensures that each signal is directed to the appropriate amplifier and combining network.
– Amplifiers: Amplifiers are used to boost the strength of the received signals. This helps to compensate for any signal loss that may occur during transmission through the coaxial cables.
– Combining network: The combining network is responsible for combining the signals from each antenna into a single output. It ensures that the signals are properly synchronized and combined without interference or loss of signal quality.
4. Output: The combined signal is then sent to the output, which can be connected to a receiver or transmitter. This output can be a coaxial cable, a connector, or any other suitable interface.
Overall, the design of an antenna combiner involves a combination of filters, amplifiers, and a combining network to receive signals from multiple antennas and combine them into a single output. This allows for improved signal strength, coverage, and quality in applications requiring multiple antennas.
An antenna combiner is used to combine the signals from multiple antennas into a single output. This is done to improve the overall performance and coverage of the antenna system. The combiner allows the signals from each individual antenna to be combined and transmitted as a single signal, which can then be received by a receiver or transmitted to a target location. The combiner is typically used in situations where multiple antennas are required to cover a large area or when multiple antennas are needed to transmit or receive signals in different frequency bands.
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The material commonly used for the PCB (Printed Circuit Board) of an antenna combiner is FR-4. FR-4 is a widely used and cost-effective epoxy-based laminate material that provides good electrical insulation and mechanical stability. It is a flame-retardant material with a high glass transition temperature, making it suitable for various electronic applications. Other materials such as F4B (a type of high-frequency laminate) may also be used in specific cases where high-frequency performance is critical.
No, an antenna combiner is not the same as a splitter.
An antenna combiner is a device that combines the signals from multiple antennas into a single output. It is commonly used in applications where multiple antennas are needed, such as in wireless communication systems. The combiner ensures that the signals from each antenna are combined without interference, resulting in a stronger and more reliable signal.
On the other hand, a splitter is a device that divides a single input signal into multiple output signals. It is commonly used in applications where a single signal needs to be distributed to multiple devices, such as in antenna distributed systems(DAS). The splitter ensures that each output receives a portion of the input signal, but it does not combine or amplify the signals like an antenna combiner does.
There are several different types of antenna combiners used in various applications. The choice of combiner depends on factors such as the number of antennas being combined, the desired frequency range, and the specific application requirements. Here are some common types of antenna combiners:
The antenna design of a passive antenna combiner is crucial to ensure efficient signal combining and minimal signal loss. Here are some key considerations in designing a passive antenna combiner:
1. Antenna Type: The choice of antenna type depends on the application and frequency range. Commonly used antennas include dipole antennas, Yagi-Uda antennas, patch antennas, or helical antennas. The antenna type should be selected to provide the desired radiation pattern, gain, and impedance matching.
2. Frequency Range: The antennas used in the combiner should cover the entire frequency range of the signals to be combined. The antennas should be designed to have a wide bandwidth to ensure efficient signal combining across the desired frequency range.
3. Impedance Matching: Each antenna should be impedance matched to the transmission line and the combiner circuit to minimize signal reflections and maximize power transfer. This can be achieved by adjusting the antenna dimensions or using matching networks.
4. Radiation Pattern: The combined radiation pattern of the antennas should be designed to meet the system requirements. This may involve adjusting the spacing and orientation of the antennas to achieve the desired radiation pattern, such as omnidirectional or directional.
5. Isolation: The antennas should be designed to provide sufficient isolation between each other to minimize interference and cross-talk. This can be achieved by proper spacing and shielding between the antennas.
6. Signal Loss: The design should aim to minimize signal loss during the combining process. This can be achieved by using low-loss transmission lines, properly designed power dividers or combiner circuits, and optimizing the impedance matching.
7. Mechanical Considerations: The mechanical design of the antennas should take into account factors such as size, weight, and mounting options. The antennas should be designed to withstand environmental conditions and provide ease of installation.
Overall, the design of a passive antenna combiner should focus on achieving efficient signal combining, minimal signal loss, and meeting the system requirements in terms of frequency range, radiation pattern, and isolation.
An active antenna combiner is a device used to combine the signals from multiple antennas into a single output signal. The main purpose of an active antenna combiner is to improve the signal strength and quality by combining the signals from multiple antennas.
The antenna design of an active antenna combiner plays a crucial role in its performance. Here are some key aspects of the antenna design in an active antenna combiner:
1. Antenna Type: The choice of antenna type depends on the specific application and frequency range. Commonly used antenna types in active antenna combiners include dipole antennas, monopole antennas, patch antennas, or helical antennas. The antenna type should have a wide bandwidth to cover the desired frequency range.
2. Antenna Configuration: The antenna configuration in an active antenna combiner can vary depending on the application. It can include multiple antennas placed in a linear array, circular array, or any other suitable configuration. The antenna configuration should be designed to achieve the desired radiation pattern and gain.
3. Antenna Gain: The antenna gain determines the amount of power that can be extracted from the received signals. Higher antenna gain helps in improving the signal strength and increasing the combiner’s overall performance. The antenna gain can be increased by using larger antenna elements or by using antenna arrays.
4. Polarization: The polarization of the antennas in an active antenna combiner should match the polarization of the incoming signals. It ensures efficient coupling of the signals into the antennas, resulting in better signal reception.
5. Impedance Matching: The antennas in an active antenna combiner should be impedance matched to the transmission line or the active components in the combiner circuitry. Proper impedance matching ensures maximum power transfer and minimizes signal reflections.
6. Noise Figure: The noise figure of the antennas used in an active antenna combiner is an important consideration. Lower noise figure antennas help in maintaining the signal-to-noise ratio and improving the overall system performance.
7. Size and Form Factor: The size and form factor of the antennas used in an active antenna combiner should be compact and suitable for the intended application. The antennas should be designed to fit into the available space without compromising on performance.
Overall, the antenna design in an active antenna combiner should focus on achieving high gain, wide bandwidth, proper impedance matching, and efficient coupling of signals. A well-designed antenna system ensures better signal quality, improved coverage, and enhanced system performance.
Designing a combiner for antennas involves several steps and considerations. Here is a general guideline to design a combiner for antennas:
1. Determine the number of antennas: Decide on the number of antennas you want to combine. This will depend on the specific application and requirements.
2. Choose the type of combiner: There are different types of combiners available, such as power dividers, Wilkinson dividers, hybrid combiners, and corporate feed combiners. Select the appropriate combiner based on your requirements and the number of antennas.
3. Determine the frequency range: Identify the frequency range over which your antennas will operate. This will help you choose the appropriate components and design parameters for the combiner.
4. Select the appropriate connectors: Choose the connectors that are compatible with your antennas and can handle the power levels and frequency range of your system. Common connector types include N-type, SMA, or BNC connectors.
5. Calculate power handling capability: Calculate the power handling capability of your combiner to ensure it can handle the combined power from all the antennas. This will help you select the appropriate power rating for the components used in the combiner.
6. Design the combiner circuit: Use a circuit design tool or simulation software(HFSS) to design the combiner circuit. You can use lumped-element components such as resistors, capacitors, and inductors, or you can use microstrip or stripline transmission line techniques.
7. Consider impedance matching: Ensure that the input and output impedance of the combiner match the impedance of the antennas and the transmission line. Impedance mismatches can lead to signal reflections and loss of power.
8. Prototype and test: Build a prototype of the combiner circuit and test it with the antennas. Measure the power output and impedance matching to verify the performance of the combiner.
9. Optimize and refine: Based on the test results, optimize and refine your combiner design if necessary. Make adjustments to improve power handling, impedance matching, or other performance parameters.
10. Finalize the design: Once you are satisfied with the performance of the combiner, finalize the design by creating a schematic and layout for manufacturing. Consider any size, cost, or other constraints for the final design.
It is important to note that designing a combiner for antennas can be a complex task, and it may require expertise in RF design and experience with simulation tools. Therefore, it is recommended to consult with an experienced engineer or RF designer if you are not familiar with the process.
Antenna combiners are crucial for efficient signal management in different environments. They save space and decrease equipment costs by allowing multiple transmitters to share one antenna. They also guarantee signal integrity. Whether you use them professionally or personally, knowing and using the right antenna combiner can make a big difference in the effectiveness and simplicity of your wireless setups.
If you want to learn more, please visit our website Combination Antennas Manufacturer.