Product Description:
The KLCG50 (Low Cost Gyro 50) is a small PC board that offers a MEMS (micro-electro-mechanical System) single-axis angular velocity sensor. Unlike other sensors, the KLCG50 is a complete unit that can measure the angular rate using only one DC voltage input. It is perfect for embedded applications as it offers installation versatility, is reasonably priced, has impressive robustness, and offers performance characteristics that can match more expensive instrument-grade rate sensors.
The KLCG50 is an ideal option for those looking to achieve high-quality performance at a lower cost. The MEMS single-axis angular velocity sensor on the board features a small form factor, making it great for use in a wide range of applications. The sensor can measure the angular rate and provide accurate results that are comparable to other expensive instrument-grade rate sensors.
Furthermore, the KLCG50 is perfect for use in embedded applications where robustness is essential. The small size of this unit makes it easy to install in various applications, while still managing to maintain optimal performance. Its low unit price and impressive performance characteristics allow it to be an ideal option for various industries and applications.
Note: The HTML code
<p> creates a new paragraph. The
<div> tag is used when you want to group HTML elements together and apply styles to them. In this case, we have used a style class called "note" which will apply formatting to the text inside the <div> tag.
Features:
● 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
Technical Parameters:
| 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] |
Physical object drawing
Applications:
Vehicle Instrumentation
One area of research and development that has seen significant progress in recent years is vehicle instrumentation. With advancements in sensor technology, data collection and analysis, and connectivity, vehicles can now be equipped with a variety of instruments to monitor critical systems and performance indicators. This allows for more efficient operation, proactive maintenance, and early detection of issues.
Robotics
Robotics has become an increasingly important field with the rise of automation and artificial intelligence. From manufacturing and logistics to healthcare and entertainment, robots are being used to perform a variety of tasks that were previously reserved for humans. Advancements in sensors, machine learning, and programming algorithms have made robots more capable, adaptable, and responsive than ever before.
Flight Testing
Before an aircraft can enter service, it must undergo a rigorous testing and evaluation process to ensure that it can operate safely and effectively under a variety of conditions. Flight testing involves subjecting an aircraft to various maneuvers and scenarios to assess its performance, stability, and controls. This process is critical for identifying and addressing potential issues before they become serious problems.
Guidance & Control Systems
Guidance and control systems are essential for ensuring the safe and accurate operation of various vehicles, from aircraft and spacecraft to missiles and drones. These systems rely on a variety of sensors and algorithms to control the vehicle's movements and maintain its stability. As technology continues to improve, we can expect these systems to become more sophisticated and capable, leading to safer and more efficient transportation.
Short Term Navigation
Short term navigation refers to the real-time tracking and positioning of a vehicle or vessel. With advancements in GPS technology and other location-based services, navigating in unfamiliar terrain has become easier and more accurate than ever before. This is especially important for high-speed vehicles that need to make quick adjustments to their course and avoid obstacles.
Ride Control -Stabilization
Ride control and stabilization systems are critical for ensuring a smooth and safe ride for passengers in various vehicles, from cars and boats to trains and planes. These systems rely on a combination of sensors and actuators to minimize vibrations, reduce noise, and maintain stability. With improvements in materials, sensors, and control algorithms, we can expect these systems to become even more effective in the future.
Support and Services:
Our Electronic Gyroscope Sensor is designed with precision to provide reliable performance for your applications. Our support includes detailed product documentation, an extensive online knowledge base, and troubleshooting guides to help you resolve any issues you may encounter.
We are committed to the satisfaction of our customers and strive to provide exceptional after-sales support. Should you have any feedback or suggestions, we welcome your input as it helps us to continuously improve our products and services.
Packing and Shipping:
The Electronic Gyroscope Sensor is housed in a robust, anti-static packaging to ensure the device remains secure and undamaged during transit. The interior of the packaging is lined with a cushioning material that absorbs shocks and vibrations, providing additional protection for the sensitive components of the sensor.
Prior to shipment, each package is sealed and subjected to a thorough inspection to guarantee that the sensor is securely enclosed. The exterior of the packaging is clearly labeled with handling instructions and the package contents to facilitate careful handling and to inform the recipient about the enclosed device.
For shipping, the packaged Electronic Gyroscope Sensor is placed in a larger, durable cardboard box designed to withstand the rigors of transport. This box is further secured with packing tape and, if necessary, additional cushioning materials are added to prevent movement within the box during shipment.
Each shipment includes a detailed packing slip with product information and a unique serial number for inventory tracking and quality control purposes. The package is then dispatched through a reliable courier service with options for tracking and insurance to ensure the Electronic Gyroscope Sensor arrives at its destination promptly and in pristine condition.
