PCTEL expanded WiFi 7 Antenna Portfolio with the Tri-band WiFi 7 Omnidirectional Antenna Platform.
This new antenna platform offers top of the line performance in a rugged, low-profile design and can operate in the full WiFi 7 frequency bands, allowing simultaneous support of multiple WiFi standards in the 2.4GHz, 5Ghz and 6GHz bands.
Highlights:
Designed to address the increasing demand for uninterrupted connectivity in critical operations where seamless, robust, and reliable connectivity is essential for our customers
Rugged design tested in harsh environments
Superior RF performance covering the Full WiFi 7 frequency range
Low profile
Competitively priced
Features:
Tri-band coverage
Slender, rugged housing (1.25″ OD)
Innovative sealed version for harsh environments
White UV-resistant fiberglass radome; protects the antenna elements from environmental factors
Easy to install
Applications:
Industrial IoT
Enterprise
Mining
The Tri-band WiFi 7 Omnidirectional Antenna platform offers unmatched signal coverage.
Rapid adoption of 5G technology and IoT devices has driven the demand for high data rate optical modules, especially from data centers for inter- and intra-communication purposes. Increasing the optical module data rate from the current 100Gbps to 400Gbps/800Gbps is an efficient way to upgrade the network infrastructure. PAM4 signal modulation and coherent technology are key for the new high data rate optical module design. To fulfill the tight design requirements of the new PAM4 type optical module, a high frequency, tight stability, low jitter, low power consumption, and small size differential crystal oscillator is very critical. As a leading company in Frequency Control Products, Taitien’s crystal oscillators are being used at the forefront of the optical module industry. Recently, we released a new series of crystal oscillators (OB-U series). Its ultra-low jitter performance (50fs typical, 100fs max), low current consumption, and smaller size (2.5 x 2.0 mm) make it the best fit for PAM4 type optical module designs for data centers, servers, and networking applications.
FEATURES
Various packages: 7.0 x 5.0 mm, 5.0 x 3.2 mm, 3.2 x 2.5 mm, 2.5 x 2.0 mm, to support flexibility and miniaturization of PCB design
Ultra low integrated phase jitter 50fs, 12kHz to 20MHz
Operation supply voltage: 1.8V, 2.5V and 3.3V
Wide operation temperature range, -45°C to 85°C, 105°C or 125°C
Multiple options for differential signal output: LVPECL /LVDS/HCSL
Operation supply voltage: 1.8V, 2.5V and 3.3V
Pb-free/RoHS compliant
APPLICATIONS
Optical transceiver modules for data center, switch and router
Precision engineering changes the way farmers manage crops, control pest infestations, take soil samples, and irrigate fields. Driven by Global Navigation Satellite Systems (GNSS), Global Positioning Systems (GPS), and wireless technology; precision agriculture advancements continue to improve crop yields, maximize operational efficiencies, and support cost-effective farming.
Field mapping
-uses GNSS to record and map the locations of rocks, potholes, power lines, poorly drained fields, pest infestations, and field fertility variations.
Tractor swath path optimization
-applies GPS to automate parallel tracking for improved operator efficiency.
Soil moisture and irrigation sensors employ
-GPS wireless technology to record moisture levels, so farmers can automatically measure, gauge, and redistribute water without manual field inspections.
Crop yield improvements
-leverage GNSS and GPS wireless data transfer technology to manage strip-till furrows, control seed usage, and minimize double planting; making farms more efficient.
Antenna Considerations
Antennas are key to accurate and successful implementation of wireless solutions for today’s modern farms.
Differential correction uses a dual-band GNSS system to mitigate the slightest errors in GPS locations caused by signal delay, multipath, satellite orbit, or timing synchronization discrepancies
GPS references accurately pick up at least three separate satellites to triangulate latitude and longitude positions plus a fourth satellite to determine elevation.
Multiband frequencies and GPS in a single radome are ideal for rovers that need to communicate with a reference base station located within five miles
Low noise characteristics prevent the GPS antenna from interfering with other on-board system communications.
Rugged design minimizes exposure to harsh chemicals, diesel fuel, axle grease, and petroleum-based products that eat away at rubber compounds.
Environmental testing ensures optimal performance during vibration, extreme temperatures, and agrochemical exposure.
Antenna Solutions
GNSS-L125-TNC Antennas
GNSS-L125-TNC Antennas achieve pinpoint accuracy with redundancy in positioning, which mitigates errors caused by multipath.
With the arrival of the 5G era, the demand for high-speed transmission is increasing. In the high-frequency and high-energy-consumption environment, the requirements for the frequency stability and accuracy of crystal oscillators are also increasing. In the past, the commonly used IEEE1588 network communication standard used a 25 MHz quartz oscillator, the display used a 27 MHz oscillator, PCIe commonly used 33.333 MHz, and recently, due to the long-term operation of fan less PC systems in high-temperature environments, products with a frequency stability of ±25 ppm or ±50 ppm have gradually been replaced with higher-precision ±10 ppm quartz oscillators to improve signal stability and network quality. Taitien Electronics has launched a new generation of ±10 ppm high-precision CMOS crystal oscillators, OY-B Type and OX-B Type, to meet the demand between ordinary oscillators and temperature-compensated oscillators, providing a cost-effective high-precision solution.
FEATURES • High Precision (±10 ppm @-40 ~ 85°C) • Low Power Consumption • Cost Effective
APPLICATIONS • Smart Meter • Wireless Communication • IoT & Portable Devices
Quartz crystal is an electronic component that utilizes the piezoelectric effect of quartz to generate high-precision oscillation frequencies. Quartz has become an important component which is widely used in various electronic devices due to its physical characteristics of low temperature coefficient and high Q value. Taitien is one of the few manufacturers who owns its in-house wafer cutting technology. By vertically integrating the production of upstream quartz wafers, wafers’ angles and thicknesses are cut precisely so as to control the material source and quality. Taitien is keenly aware of the mainstream development of electronic products that are light and thin, as well as the demand for high-speed transmission and high-frequency communication. We provide a variety of miniature, low-power consumption, high-precision and wide-temperature quartz crystals to satisfy customers’ diversified needs for quartz components.
TAITIEN Advantage
Industry 4.0 is introduced to build the Internet of Machines and realize smart manufacturing to satisfy customers’ needs
Quartz crystal and oscillation circuit loop analysis are provided to enable customers to find the most stable matching combination
Readily available with better delivery time which quickly support samples and follow-up mass production service
Applications
5G mobile phone (smart phone), smart meter, smart home, IoT, Wi-Fi 6/6E, Bluetooth, Low-Power Wide Area Network (LPWAN), desktop/ notebook/ gaming computers, smart cockpit, in-vehicle communication, long and short-range radar, car infotainment and edge computing products
Key Products
>>kHz Quartz Crystal Series (kHz XTAL)
High stability: annual aging rate lower than ±3 ppm
High Q (quality factor) value: tuning fork crystal design
Low power consumption: drive Level of 0.1 ±0.01 uW
>>MHz Quartz Crystal Series (MHz XTAL)
Excellent frequency stability as low as ±5 ppm
Wide temperature range which complies with automotive requirements from -40°C to +125°C
Ultra-small package and ultra-thin of 0.3 mm which is ideally suited for low circuit board height or ultra-small wearable applications
>>High Precision Quartz Crystal Series (High Precision XTAL)
Excellent power-on characteristics: Since the thermal overshoot of a SC-cut resonator is about 2 orders of magnitude smaller than an AT-cut, the SC-cut crystal oscillator can quickly reach its frequency stability after powering up. In general, the stability can reach 2×10-9 after powering up for 6 minutes.
Low aging: The stress effect of the SC-cut resonator is small and the aging caused by stress relaxation is also small. The aging rate can reach 10-11/d.
Outstanding short-term frequency stability: After the drive level is increased, the signal-to-noise ratio relative to the white noise is increased, thus the far-end phase noise can be improved. Currently, the highest level can reach -160~-170 dBc/hz.
We are pleased to announce an addition to PCTEL’s LPCA family – LPCA-MIMO 5G Ready Antenna.
LPCA-MIMO 5G offers excellent RF performance in a discreet, rugged, low-profile design supporting, Cellular MIMO 4×4 LTE/5G, GNSS or 2×2 LTE/5G, and 2×2 MIMO WiFi-6E in a low profile casing with durable design.
The antenna platform is configurable, enabling adaption to your antenna system needs. LPCA-MIMO 5G standard configuration contains two cellular band antennas designed for 617-960 MHz / 1710-2690 MHz / 3300-5000 MHz, two secondary LTE/WiFi-6E antennas 1427-7125MHz, and a LNA equipped GNSS antenna.
The LPCA-MIMO antenna platform is designed to support multi system solutions making it perfect for fleet management, track and trace, navigation, cargo handling, and V2X. Dual feed GNSS antennas enable excellent axial ratio and gain. Pre-filtered LNA ensures functionality in a combination antenna.
The LPCA-MIMO 5G Ready Antenna Platform is a multiport antenna with unique discrete design that provides reliable connectivity for smart transit and precision agriculture.
The Shield Can and Clip range from Harwin is based on the concept of fast assembly and component protection. Designed for use within an existing SMT circuit board layout, these products are a simple and cost-effective method of shielding vulnerable or EMI-radiating board components.
By using a push-action, the removable shield can is held in place with SMT mounted spring clips, so no additional secondary soldering operation is required. All soldering takes place on the clip, at the same time as the rest of the PCB components. This eliminates the risk of heat damage and hot spots (caused by hand soldering) affecting the more expensive components located under the can.
The devices under the can are also now accessible at any time, by simply pulling out the can from the clips. Rework and module replacement can be completed, and the can is simply pushed back into place again.
Shield Cans are available in three different material thicknesses (0.3, 0.2 and 0.15mm) to assist matching to different EMI / RFI characteristics. Clips are supplied in a variety of shapes and sizes for added design flexibility.
Features and Benefits:
No soldering required for can assembly
Eliminate secondary soldering operations and the damage risk from hot-spots
SMT clips supplied on Tape and Reel
Enables fast, fully automated PCB assembly, at the same time as other components
Fast and simple push-fit with SMT clips
Quick secondary operation for reduced assembly costs
Easy to remove in a single action
Simple to rework or upgrade covered devices
Re-usable can once removed
No de-soldering clean-up activity required
Choice of material thicknesses
Different EMI / RFI shielding characteristics
Ready-made can sizes and clips available from stock
Fast delivery, easily purchased from a global authorized distribution network
Key Applications:
Energy
Renewable Sources, Home Energy meters, E-vehicles
Telecommunications
Base Stations, WiFi, Wireless Modules, IOT, Handheld devices
Industrial
Drives and Controls, Robotics, IIOT, Wireless Modules
Motorsport
Wireless communications and Telemetry, Navigation and Tracking, Control Systems
Space
Satellites, CubeSats, Launch Systems
Aviation, Defense, Security
UAVs, Avionics, Aircraft infotainment, Radar, Mobile Communications, Vehicle Control systems, Wireless Telemetry
We are pleased to announce the addition of the VerStack platform to PCTEL portfolio of 5G ready antennas.
The VerStack platform consists of the most advanced 5G and GNSS vertically stacked antennas in the market. It utilizes PCTEL’s broadband element technology to provide top-of-the-line RF performance in rail and IIoT applications. These antennas have been designed in a rugged UV-resistant fiberglass housing making them ideal for harsh environmental conditions. The VerStack platform is easy to install and offers 3:1 and 5:1 configuration.
Product Highlights:
Very rugged, designed to meet wayside rail specifications
Vertically stacked solution for multiple ports
Pole mounted
Features:
Wideband coverage
High rejection GPS LNA technology
Dual port MIMO design
High quality low loss cable and connectors
Easy to install
Rugged, UV-resistant fiberglass housing
Applications:
Industrial IoT
Rail
Intelligent Transportation Systems
Frequency Ranges:
617 – 960 MHz
1710 – 2700 MHz
3200 – 4200 MHz
4900 – 6000 MHz
The VerStack platform is the most advanced 5G and GNSS vertically stacked antennas in the market for Rail, IIoT and ITS applications.
The ultimate Hi-Rel connector for power handling capability and voltage flashover resistance. Fully rugged construction to withstand shock and vibration, but compact and lightweight compared to equivalent connections. Thumbscrew fixings for easy strain relief on cable-to-board connections.
Applications:
Aviation: Power control systems, in-flight infotainment & in-cabin services, navigation and flight systems. Motorsport & EV: Battery control and monitoring systems, ERS control& supply, auxiliary system power, cabin systems. Space: Satellites & CubeSats, communications, launch systems, power supplies. Defense & Security: UAVs, rugged vehicle electronics, remote robotics drives, servo controls. High-end Industrial: Power units and power control systems, robotics drives and servo controls, mining or oil & gas power systems.
Features:
Ensure continuous current integrity under extremes of bump, vibration and shock with tough housings and stainless steel screw-locks
Prevent contact damage and mis-mating – individually shrouded contacts sit in a rugged housing design with double polarization features
Benefit from Harwin’s cable assembly expertise, 100% inspected and tested harnesses, or choose do-it-yourself components
Fast contact identification in production with No. 1 contact position marked on housings
Mate-before-lock screw fixings for quick and simple connector mating-choose thumbscrews or front panel mounting
Precision engineering changes the way farmers manage crops, control pest infestations, take soil samples, and irrigate fields. Driven by Global Navigation Satellite Systems (GNSS), Global Positioning Systems (GPS), and wireless technology; precision agriculture advancements continue to improve crop yields, maximize operational efficiencies, and support cost-effective farming.
Field mapping
-uses GNSS to record and map the locations of rocks, potholes, power lines, poorly drained fields, pest infestations, and field fertility variations.
Tractor swath path optimization
-applies GPS to automate parallel tracking for improved operator efficiency.
Soil moisture and irrigation sensors employ
-GPS wireless technology to record moisture levels, so farmers can automatically measure, gauge, and redistribute water without manual field inspections.
Crop yield improvements
-leverage GNSS and GPS wireless data transfer technology to manage strip-till furrows, control seed usage, and minimize double planting; making farms more efficient.
Antenna Considerations
Antennas are key to accurate and successful implementation of wireless solutions for today’s modern farms.
Differential correction uses a dual-band GNSS system to mitigate the slightest errors in GPS locations caused by signal delay, multipath, satellite orbit, or timing synchronization discrepancies
GPS references accurately pick up at least three separate satellites to triangulate latitude and longitude positions plus a fourth satellite to determine elevation.
Multiband frequencies and GPS in a single radome are ideal for rovers that need to communicate with a reference base station located within five miles
Low noise characteristics prevent the GPS antenna from interfering with other on-board system communications.
Rugged design minimizes exposure to harsh chemicals, diesel fuel, axle grease, and petroleum-based products that eat away at rubber compounds.
Environmental testing ensures optimal performance during vibration, extreme temperatures, and agrochemical exposure.
Antenna Solutions
Omnidirectional BOA Series Base Station Antennas, placed with a GPS-TMG antenna at a silo elevator or distribution station improve communication accuracy.
