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Pressure displacement analyzer is a professional instrument used to measure the deformation of materials under force. It can measure the pressure, strain, displacement and other mechanical parameters of the material, and analyze and process the parameters through the built-in software system and algorithm, so as to obtain the mechanical properties of the material. Pressure and displacement analyzer is widely used in material science, machinery manufacturing, construction engineering, aerospace and other fields. With the continuous progress of science and technology and the rapid development of industrial manufacturing, the requirements for the mechanical properties of materials in industrial production are also rising, so more accurate and reliable measuring instruments are needed to meet the demand. The emergence of stress-strain displacement analyzers fills the gap in material mechanics performance testing equipment, greatly enhancing the accuracy and efficiency of material testing. The characteristics of stress-strain displacement analyzers to be considered during use include: High-precision measurement: It can measure the displacement change of the object under the action of pressure with high precision to ensure the accuracy and reliability of the measurement results； High reliability: It can measure stably for a long time under extreme conditions, and is suitable for various complex environments and application scenarios； The operation is simple, and the complex measurement task can be realized through simple operation, so that the work efficiency is improved； Multi-functional: It can perform various functions such as automatic recording, data processing, result analysis, and report generation to meet the needs of different application scenarios； Intuitive display: Pressure displacement analyzers usually have LCD displays, which can intuitively display measurement results and parameters, making it easy for users to carry out real-time monitoring and data analysis； Convenient data processing: Measurement data can be stored in the internal memory or external devices, and support a variety of data format export, convenient for users to carry out later data processing and analysis. Forlinx Embedded recommends using FETMX8MM-C as the product implementation solution. In this solution, the main functions of the i.MX8MM-C SoM are: The human-machine interaction module displays real-time data transmitted from the MCU via MIPI, and performs drawing and data display； Data processing and storage is achieved through USB interface conversion to ULPI LINK for communication with the MCU end. Data is received and stored in TF cards or USB drives, then processed to output in a more concise and understandable form； Network transmission and remote control are facilitated through a Gigabit Ethernet port, allowing for remote monitoring of screens, network backups, and system parameter restoration. Advantages: Equipped with an ARM Cortex-A53 quad-core CPU running at 1.8GHz and paired with 2GB of DDR4 RAM, it offers high performance and computational power, providing a significant advantage in data processing； The compact size of only 56mm * 36mm meets the requirements of miniaturization and portability of equipment and reduces the size of products； Support 4-line mipi display, maximum 1.5g bps transmission, high-definition output image； Long supply cycle, join NXP product long-term supply plan, guarantee at least 10 years of supply period； The operating environment temperature ranges from -40°C to 85°C, meeting the requirements for industrial and general industrial applications. The above is the pressure displacement curve analysis solution provided by Forlinx Embedded based on the FETMX8MM-C SoM. We hope it can assist you in your selection process.

A blood cell analyzer is one of the widely used instruments in clinical laboratory testing in hospitals. It classifies white blood cells, red blood cells, and platelets in the blood using the resistance method. It can also provide data related to blood such as hemoglobin concentration and hematocrit. In clinical applications, it can be used for white blood cell counting, neutrophil counting, lymphocyte counting, red blood cell counting, and other clinical tests. It is an important reference for doctors to diagnose patients' conditions. Function requirements Detection parameters: The instrument should be able to detect common blood parameters including red blood cells, white blood cells, platelets, hemoglobin, and white blood cell differentials. Sample handling: The instrument should be capable of automated sample loading, sample distribution, cleaning, and waste disposal. Accuracy: The instrument should have high measurement accuracy and repeatability to meet clinical diagnostic requirements. Usability: The instrument should have a user-friendly interface that is easy to operate, allowing laboratory personnel to use it with ease. Data analysis: The instrument should have the capability to automatically generate test reports and perform basic data analysis based on the test results. Hardware design requirements Controller: A high-performance microprocessor is used as the main controller of the instrument, which is responsible for realizing various control logic and data processing. Power supply module: Use a stable power supply module to ensure consistent instrument performance in various environmental conditions. Detection Module: According to the blood indexes to be detected, design the corresponding detection module, such as optical detection module, electrical detection module, etc. Detection Module: According to the blood indexes to be detected, design the corresponding detection module, such as optical detection module, electrical detection module, etc. Human-computer interaction: Use a touch screen as the operation interface, which is convenient for laboratory staff to use. At the same time, it has a printing function, which can print out the test results. Data storage: Data can be stored through built-in memory chip and SD card. Design scheme For the functional characteristics of the blood analyzer, Forlinx Embedded recommends the FETMX8MM-C system on module as the hardware development platform, which is equipped with ARM Cortex-A53*4+Cortex-M4 processor with 1.8GHz main frequency. It supports LPDDR4 and eMMC storage to configure the appropriate memory and flash on demand. i.MX8MM SoM With multiple interfaces: It includes display interface, supports external screens of various specifications and sizes, and is compatible with resistive capacitive touch, providing excellent human-computer interaction experience. USB interface is convenient to connect external devices, such as U disk, mouse, WiFi, 4G, printer, etc. The network interface includes 10/100/1000M Ethernet, 4G module and WiFi module to realize efficient communication with hospital HIS and laboratory information system LIS. The SPI bus is used to extend the FPGA to support various applications such as motor control, gate valve control, and AD sampling. The serial port is used to communicate and control with the bar code machine, the lower electromechanical structure and other equipment. For external storage, TF and SD cards are supported for storing computing data, analyzing results, and so on. The FETMX8MM-C Core board has a wide range of applications in the medical field, providing high-performance and multi-functional processing power for medical devices, and helping to realize a smarter and more convenient medical information system.