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| Place of Origin: | China (Mainland) |
| Brand Name: | Kacise |
| Certification: | certificate of explosion-proof, CE |
| Model Number: | KLCG50 |
| Minimum Order Quantity: | 1pcs |
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| Packaging Details: | each unit has individual box and all boxes are packed in standard packages or customers requests available |
| Delivery Time: | 5-8 working days |
| Payment Terms: | T/T, Western Union, MoneyGram |
| Supply Ability: | 1000 Pieces per Week |
| Operating Temperature: | -40°C To +85°C | Input Voltage: | +5.0 Vdc |
|---|---|---|---|
| Storage Temperature: | -55°C To +100°C | Vibration Operating: | 5 Grms |
| Input Current: | < 8 MA @ +5.0 Vdc | Weight: | < 0.4 Oz. [12 Grams] |
| Start-Up Time(Typical): | < 2s | Vibration Survival: | 10 Grms |
| High Light: | analog Voltage output MEMS rate sensor,2s Start-Up MEMS rate sensor |
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The KLCG50, or Low Cost Gyro 50, is a small PC board featuring a single-axis angular velocity sensor that utilizes MEMS (micro-electro-mechanical System) technology. This sensor is a self-contained unit that only requires one DC voltage input to measure the angular rate.
The LCG50 is primarily designed for embedded applications that demand installation versatility, robustness, and affordability. Despite being available at a low unit price, the performance characteristics of this sensor are impressive enough to match those of more expensive instrument-grade rate sensors.
By using this sensor, developers can save both development time and money without sacrificing performance.
The LCG50 is an ideal solution for a wide range of embedded applications, including robotics, drones, electronic stability control in automobiles, camera stabilization systems, and even navigation systems.
Thanks to its compact size and versatile installation options, the KLCG50 is also well-suited for applications where space is limited, making it highly adaptable to the needs of various projects.
● Proven MEMS Technology
● DC Voltage Output
● Wide Bandwidth
● Analog Voltage Output
● Low Power Consumption
● High Reliability
● Wide Operating Temperature Range
● Small Size
● Fast Start-Up
● DC in DC out
● Temperature Sensor Output
| Parameter | KLCG50-00020-100 | KLCG50-00100-100 | KLCG50-00250-100 | KLCG50-00500-100 |
| Power Requirements | ||||
| Input Voltage | +5.0 Vdc | |||
| Input Current | < 8 mA @ +5.0 Vdc | |||
| Performance | ||||
| Standard Range Full Scale | ± 20°/sec. | ± 100°/sec. | ± 250°/sec. | ± 500°/sec. |
| Scale Factor Calibration(at 22°C) | 50 mV/°/sec ± 15% | 16 mV/°/sec ± 15% | 6.4 mV/°/sec ± 15% | 3.2 mV/°/sec ± 15% |
| Scale Factor over Temperature | < 0.1%/°C | |||
| Bias Calibration(at 22°C) | +2.5 Vdc ± 0.6 Vdc | +2.5 Vdc ± 0.6 Vdc | +2.5 Vdc ± 0.6 Vdc | +2.5 Vdc ± 0.6 Vdc |
| Bias Variation over Temperature | 10°/sec. | 8°/sec. | 10°/sec. | 20°/sec. |
| G Sensitivity(Typical) | < 0.05°/sec/g | |||
| Start-Up Time(Typical) | < 2.0 sec. | |||
| Bandwidth(-3 dB) | > 50 Hz | |||
| Non-Linearity(% Full Range) | < 0.05% | |||
| Output Noise(DC to 100Hz) | ≤ 0.005°/sec./√ Hz | ≤ 0.005°/sec./√ Hz | ≤ 0.006°/sec./√ Hz | ≤ 0.01°/sec./√ Hz |
| Scale Factor(Temperature Sensor) | 6.25 mV/°C Typical | |||
| Output Voltage at 0°C(Temperature Sensor) | +424 mV Typical | |||
| Environments | ||||
| Operating Temperature | -40°C to +85°C | |||
| Storage Temperature | -55°C to +100°C | |||
| Vibration Operating | 5 grms | |||
| Vibration Survival | 10 grms | |||
| Shock | 500g PK ½ sine 2msec | |||
| Weight | < 0.4 oz. [12 grams] | |||
Vehicle Instrumentation involves the application of technologies to monitor and display a vehicle's performance and status. This data can be essential in helping drivers and mechanics identify issues and optimize performance. Modern vehicle instrumentation systems often include features like real-time data streaming, customizable displays, and integrated fault detection.
Robotics is the application of technology to create machines that can perform complex tasks autonomously or under remote control. Robotics has applications in industrial automation, manufacturing, medicine, space exploration, and many other fields. Modern robotics systems often include advanced sensing and AI capabilities to enable precise and efficient motion control.
Flight Testing is the process of evaluating the performance and safety of aircraft in real-world flight conditions. This process involves a variety of tests and measurements, including aerodynamics, flight dynamics, engine performance, and structural integrity. Flight Testing is essential to ensure that aircraft meet safety standards and perform as expected in a variety of scenarios.
Guidance & Control Systems are used to direct the motion of vehicles or other systems in real-time. These systems often include sensors, processing units, and communication channels to provide precise and reliable control. Applications of guidance and control systems include autonomous vehicles, robotics, aircraft, and spacecraft.
Short Term Navigation refers to the ability to plan and execute accurate and efficient movement over short distances. This capability is essential in many applications, such as logistics, manufacturing, and emergency response. Short term navigation systems may rely on technologies like GPS, laser sensing, or computer vision to understand the immediate environment and plan safe and effective movement.
Ride Control - Stabilization involves the application of technologies to improve the comfort and safety of vehicles in motion. This can include active suspension systems, anti-roll bars, and other technology to reduce vibrations, sway, and other undesirable effects. Ride control and stabilization technologies are particularly important in high-speed or off-road applications, where vehicle stability and safety can be a critical concern.
Our Electronic Gyroscope Sensor is designed to provide precise motion sensing in a variety of applications. Our product technical support and services are dedicated to ensuring that you can integrate and use our gyroscope sensor effectively in your projects.
Technical Support:
- Comprehensive online documentation: Access detailed product specifications, integration guides, and troubleshooting articles to assist you with any technical queries regarding our Electronic Gyroscope Sensor.
Services:
- Email support: Reach out to our dedicated support team for personalized assistance with any technical issues you may encounter.
We are committed to providing you with the support you need to utilize our Electronic Gyroscope Sensor to its fullest potential.
Product Packaging:
The Electronic Gyroscope Sensor comes securely packaged in an anti-static bag to prevent any electrostatic discharge during handling. The bag is then placed in a custom-fit foam insert that snugly holds the sensor in place, ensuring maximum protection against physical shocks and vibrations. This foam is encased in a sturdy cardboard box which is sealed and labeled with the product information and handling instructions. The packaging has been designed to be compact while offering the best possible protection for the sensitive electronics inside.
Shipping:
Once the Electronic Gyroscope Sensor is packaged, it is ready for shipping. The boxed product is placed in a secondary, larger cardboard box with additional cushioning material to fill any void space, minimizing movement during transit. Fragile stickers are applied to the outer box to alert couriers that the contents require careful handling. The package is then sealed with heavy-duty packing tape and dispatched using a reliable shipping service that provides a tracking number. Customers will receive their tracking information via email to monitor their package's journey until delivery.
Contact Person: Ms. Evelyn Wang
Tel: +86 17719566736
Fax: 86--17719566736
Address: i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
Factory Address:i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
