1064nm All-in-One Fiber AOM Series In-depth Analysis: Integrated Driver + Low Loss Design

1064nm All-in-One Fiber AOM Series In-depth Analysis: Integrated Driver + Low Loss Design

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In the field of optoelectronic technology, the 1064nm integrated optical fiber AOM (Acousto-optic modulator) series has become a key component in numerous application scenarios due to its unique advantages. It integrates drivers and devices, and has emerged as a leader in optical modulation applications with its high integration, small size, and high-frequency stability. The following will provide an in-depth analysis from dimensions such as product features, specification parameters, and application scenarios.

 

Core product features: Integration and performance combined

The most prominent feature of the 1064nm integrated optical fiber AOM series is its high integration, which integrates the driver and the device, simplifies the system structure, saves space, and facilitates equipment integration and miniaturization design. The low insertion loss feature ensures efficient optical signal transmission, reduces energy waste, and improves the utilization rate of the system's optical power. The low-power design meets the energy-saving requirements, reduces the operating costs and heat generation of the equipment, and is conducive to stable operation. At the same time, it features high-temperature stability and reliability. In complex environments, especially in scenarios with temperature fluctuations, such as high-temperature industrial production processes and outdoor environmental monitoring, it can still operate stably, ensuring precise optical modulation and laying a solid foundation for the reliable operation of the system.

 

Specification parameters: Precisely adapted to diverse demands

In terms of wavelength, it covers 1030-1080nm and can be used as a typical light wavelength indicator. It also supports the selection of other wavelengths and frequencies, making it suitable for different light sources and applications. The frequency shift comes in specifications such as 80MHz, 150 MHZ, and 200MHz. The insertion loss varies with the frequency shift. For instance, when the frequency shift is 80 MHZ, the insertion loss is less than 2.5dB. The larger the frequency shift, the slightly higher the upper limit of the insertion loss. When designing and applying, it is necessary to balance the frequency shift requirements and the loss. The rise time is at the nanosecond level, with a frequency shift of less than 12ns at 200MHz. The rapid response facilitates high-speed optical modulation, meeting the high modulation speed requirements of scenarios such as ultrafast laser frequency reduction menus. The types of optical fibers include PM980 (PM), HI1060 (SM), or others, which are suitable for different optical fiber transmission systems to ensure the appropriate transmission of optical signals.

 

Rich application scenarios: Shining in multiple fields

In Q-switched fiber lasers, it is the core modulation component. Through precise light modulation, it controls the output of laser pulses to achieve high-energy, narrow-pulse width laser generation. It is applied in industrial processing such as laser marking and cutting, making the marks clearer and the cuts more precise. In the application of laser Doppler phase, by leveraging its optical modulation capability, the phase changes of light can be precisely controlled, facilitating speed measurement, flow measurement, etc. In fields such as traffic speed measurement and fluid monitoring, it provides support for precise data collection. The ultrafast laser frequency reduction menu scenario utilizes the fast modulation characteristics to reduce the frequency of ultrafast lasers, expand the application band of lasers, and meet the specific frequency laser requirements of scientific research, biological imaging, and other fields. In terms of linear frequency modulation, it can achieve linear changes in the frequency of optical signals. In fields such as optical communication and radar signal simulation, it provides new means for signal modulation and coding, enhancing communication capacity and radar detection accuracy.

 

Installation and Adaptation: Details ensure performance

Its optical fiber connector adopts FC/APC to ensure stable and low-loss optical connection. During installation, it is necessary to pay attention to cleaning the connection end face to avoid contamination affecting optical transmission. The working voltage is 12±0.5V DC. The power interface is a through-core capacitor (with the core wire connected to the positive terminal and the solder sheet connected to the negative terminal). It needs to be matched with a stable DC power supply to ensure accurate power supply and maintain the stable operation of the device. The mechanical specifications such as the external dimensions and installation hole positions must be strictly followed during design and installation to ensure compatibility with the equipment structure and avoid mechanical stress affecting the performance of the components. For example, when integrated into the laser equipment cabinet, they should be precisely installed and fixed to ensure long-term stable operation.

 

The 1064nm integrated optical fiber AOM series, with its integration, high performance and multi-adaptability, has great potential in optoelectronic applications. With the increasing demands for optical modulation accuracy and integration in fields such as optical communication, laser processing, and scientific research, it will continue to be optimized and upgraded, injecting optical modulation impetus into the innovative development of various industries, becoming an indispensable "optical modulation expert" in optoelectronic systems, and promoting the continuous expansion of the application boundaries of optical technology.

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