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Non-contact, ultra-thin, lightweight, and compact, these encoders are ideal for integration into space-constrained devices. Their large hollow design, absolute mode functionality, and high-speed operation cater to a wider range of applications. Hysteresis-free, high dynamic range, and up to 20-bit resolution, they are compatible with various communication interfaces. They possess high resistance to shock and vibration, and operate within a temperature range of -30°C to +85°C. The IAM series magnetic encoders feature built-in advanced self-monitoring capabilities and offer single-turn and multi-turn options.

The product consists of a stator and inner and outer dual-code disk rotors, employing electromagnetic field stacking and recognition technology to achieve a Single-Sided Dual-Encoding in an ultra-thin and ultra-narrow size. It features high precision, low power consumption, and an ultra-thin profile, resulting in a very compact structure. The DIAP single-sided dual-encoding encoder also has two independent position detection and signal output mechanisms, making it ideal for applications in space-constrained equipment such as robot joints or multi-axis automation systems. Customized expansion options are also available to perfectly meet customer needs.

The product consists of three parts: a stator and two rotors, with the two rotors positioned on either side of the stator. It features high precision and a large hollow core. Both the stator and rotors can be fastened with screws, making installation quick and convenient. The DIAP dual-sided dual-encoder has two independent position detection and signal output mechanisms. This product can achieve simultaneous measurement and output at high and low speeds, and can also be used for backup and redundancy applications, greatly increasing product reliability.

The non-contact IAC series utilizes inductive technology, offering a robust and easy-to-install design. Its large hollow structure allows for easy passage of cables, optics, conduits, and other system components. The products are easily integrated into systems without requiring precision-machined mounting parts or couplings. High-precision, compact designs with a stator containing all received power and output signal electronics are equipped with various communication interfaces and offer customized expansion options.

The IAS series inductive encoders are advanced position sensors. The product consists of a rotor and a stator, both with a ring-shaped, hollow structure for easy installation. The large hollow core facilitates the passage of shafts, cables, and other components, eliminating the need for couplings during installation. Non-contact operation, high precision, absolute value measurement, and a compact design enable them to deliver superior performance, meeting the demands of demanding industrial environments. They are specifically designed for a wide range of industrial automation and motion control applications.

Designed specifically for robotic dexterity hands, the MIAP series utilizes a unique limited-space electromagnetic field confinement and enhancement technology to achieve high-intensity inductive signal transmission within a mere ten millimeters of outer diameter and two millimeters of space, breaking through the small-size barrier of inductive encoders. The MIAP series combines small outer diameter, ultra-thin design, high precision, and high reliability, injecting ultimate precision into humanoid robot dexterity hands and achieving pinnacle of operational capabilities.

Ultra-thin, lightweight, hollow, and non-contact, frictionless design, making it ideal for space-constrained applications. Its compact structure allows for perfect mounting in robot joints or multi-axis automation applications, serving both as position feedback and for optimizing commutation of frameless motors. Tested and proven to meet stringent industrial environmental requirements, the non-contact absolute IAP encoder is designed for efficient, accurate, and reliable position sensors, and is available with customization options.