logo
Send Message

CHNSpec Technology (Zhejiang)Co.,Ltd chnspec@colorspec.cn 86--13732210605

About Us
Why Choose Us
CHNSpec Technology (Zhejiang)Co.,Ltd was found in 2008, and we are specialize in the R&D, production and sales of colorimeters.
View More
CHNSpec Technology (Zhejiang)Co.,Ltd

HIGH QUALITY

Trust Seal, Credit Check, RoSH and Supplier Capability Assessment. company has strictly quality control system and professional test lab.
CHNSpec Technology (Zhejiang)Co.,Ltd

DEVELOPMENT

Internal professional design team and advanced machinery workshop. We can cooperate to develop the products you need.
CHNSpec Technology (Zhejiang)Co.,Ltd

SOURCE FACTORY

Advanced automatic machines, strictly process control system. We can manufacture all the Electrical terminals beyond your demand.
CHNSpec Technology (Zhejiang)Co.,Ltd

INTIMATE SERVICE

Bulk and customized small packaging, FOB, CIF, DDU and DDP. Let us help you find the best solution for all your concerns.

2013

Year Established

200+

Employees

100000+

Customers Served

30000000+

Annual Sales

Our Products

Featured Products

China CHNSpec Technology (Zhejiang)Co.,Ltd
Contact Us
Play video
Contact at Any Time
Send

CHNSpec Technology (Zhejiang)Co.,Ltd

Address: No. 166 of Wenyuan Road,Jianggan District,Hangzhou City, Zhejiang Province, China
Fax: 86--13732210605
Phone: 86--13732210605
Our Products
Top Products
Our Cases
Recent Industrial Projects
Lastest company cases about The important application of haze meters in the glass industry
2025/07/23
The important application of haze meters in the glass industry
In today's materials science and manufacturing industry, as a widely used material, it is of great significance to accurately evaluate the optical properties of glass. The haze meter, as a precision device specifically designed for measuring the haze and light transmittance of materials, plays an irreplaceable role in the field of glass.   Haze refers to the cloud-like or cloudy appearance formed on the interior and surface of transparent or semi-transparent materials due to light scattering, which is expressed as a percentage of the ratio of the diffused light flux to the light flux passing through the material. Transmittance refers to the ratio of the luminous flux passing through the material to the incident luminous flux. The haze and light transmittance of glass directly affect its visual effect, optical properties, and performance in various application scenarios.     In the field of architectural glass, glass with low haze and high light transmittance can provide a clear view, allowing the interior to fully bask in natural light, and can also effectively reduce heat transfer, achieving the goal of energy conservation and environmental protection. Haze meters can assist manufacturers in strictly controlling the quality of glass and ensuring that it meets the standards of architectural design. For instance, when choosing curtain wall glass for high-rise buildings, with the precise measurement of a haze meter, glass with excellent optical performance can be selected to prevent visual blurring or reflection caused by excessive fog on the glass, which could affect the overall aesthetic appeal and user experience of the building.   In terms of automotive glass, the front windshield, window glass and other components not only need to have good light transmittance to ensure a clear field of vision for the driver, but also need to keep the haze within an appropriate range to reduce the interference caused by light scattering to driving. Haze meters can provide precise data for automotive glass manufacturers, helping to develop safer and more comfortable automotive glass products. In addition, the haze meter can also conduct an effective assessment of the anti-fog treatment effect of automotive glass.   In the field of optical glass, such as that used for camera lenses, telescopes, microscopes, etc., the requirements for haze and light transmittance are more stringent. Even the slightest difference in haze can affect the imaging quality and clarity of the optical system. The high-precision measurement of haze meters can help optical glass manufacturers strictly control product quality and produce high-quality glass that meets the demands of high-end optical applications.     In addition to quality control during the production process, haze meters also play a crucial role in the research and development and performance optimization of glass. Researchers can optimize the production process of glass by measuring the haze and light transmittance of glass produced under different formulas and process conditions, and develop new types of glass materials with specific optical properties.     In conclusion, the application of haze meters in the glass industry covers all aspects from production to research and development, providing strong technical support for ensuring the optical performance quality of glass and promoting the innovative development of glass materials. With the continuous advancement of technology and the increasing demands for the optical performance of glass, the significance of haze meters will become more prominent, serving as a crucial driving force for the sustained development of the glass industry.
Lastest company cases about Revealed: Why Are color matching Software gradually replacing Manual color matching?
2025/07/21
Revealed: Why Are color matching Software gradually replacing Manual color matching?
In today's colorful world, whether in the design industry, industrial production or artistic creation, precise and creative color matching holds a crucial position. With the continuous advancement of technology, color-matching software has gradually become the first choice for many people, replacing the traditional manual color-matching mode. Now let's elaborate on several key reasons why color matching software should be chosen over manual color matching:   First, the accuracy has been significantly enhanced Color-matching software is built based on precise mathematical operation rules and a vast color database, and can provide highly accurate color-matching schemes. It can precisely calculate the proportional relationship between different colors, effectively ensuring the consistency and stability of colors. In contrast, artificial color matching is highly susceptible to interference from human factors, such as visual fatigue, emotional fluctuations, and limitations of personal experience. Even experienced professionals cannot guarantee that every color matching will be completely accurate and error-free. Color-matching software, on the other hand, can eliminate these uncertainties and present reliable color-matching results to users.     Secondly, efficiency has been significantly enhanced In today's fast-paced modern society, time is truly invaluable. Color-matching software can generate a large number of color-matching schemes in an extremely short time, greatly improving work efficiency. Users only need to input some key parameters, such as the main color tone and style preference, and the software can quickly provide multiple feasible options. This is particularly crucial for those situations where design projects need to be completed quickly or urgent production demands need to be met. In contrast, manual color matching requires a considerable amount of time for experimentation and adjustment, and its efficiency is often relatively low.   Thirdly, the space for creativity is even broader Color-matching software usually features a rich and diverse color library as well as innovative algorithms, which can provide users with more sources of creative inspiration. The software can generate various unique color schemes according to different needs and styles, some of which are even difficult for humans to conceive. This enables designers and creators to break through the traditional thinking framework and open up a broader creative space. In addition, the color-matching software can conveniently adjust and combine colors, allowing users to easily try different creative schemes and thus find the most suitable color matching.     Fourth, the color management is more outstanding Color management is of vital importance in the design and production processes involving multiple links and different equipment. Color-matching software can ensure that colors remain consistent across different devices and media, effectively avoiding color difference issues. The software can adjust and optimize colors according to different output requirements. Whether it is printing, screen display or product manufacturing, it can ensure the accuracy and stability of colors. However, manual color matching is relatively difficult in terms of color management and it is hard to achieve consistency in different environments.   Fifth, it offers better cost-effectiveness In the long run, choosing color-matching software can bring higher cost-effectiveness. Although purchasing color-matching software may require a certain initial investment, compared with the human and time costs needed for manual color-matching, the cost of the software is relatively low. In addition, the software can be reused and continuously updated and upgraded along with technological development, providing users with better services. For enterprises, using color-matching software can enhance production efficiency, reduce costs and strengthen market competitiveness.     Sixth, it is easy to learn and use Modern color-matching software is usually designed to be very user-friendly, making it easy to operate even without professional color knowledge. The software offers an intuitive interface and a simple operation process. Users can perform color matching operations by dragging, clicking and other methods. Meanwhile, the software usually provides detailed instructions and tutorials to help users quickly master the usage methods. In contrast, manual color matching requires professional training and rich experience, and the learning cost is relatively high.   In conclusion, choosing color matching software instead of manual color matching has many advantages. It can offer higher accuracy, faster efficiency, a broader space for creativity, better color management, higher cost-effectiveness, and is easy to learn and use. In today's digital and intelligent era, color-matching software is undoubtedly the best choice for achieving excellent color matching.
Lastest company cases about The relationship between glossiness and color of printed matter and the measurement methods
2025/07/14
The relationship between glossiness and color of printed matter and the measurement methods
In the field of printing, the quality assessment of printed materials is a complex and crucial step, among which glossiness and color are two important characteristics. There is a close relationship between them, and an accurate measurement method is crucial for ensuring the quality of printed matter.     The glossiness of printed matter has a significant impact on the presentation of color. Higher gloss can enhance the saturation and contrast of colors, making them more vivid, bright and lively. This is because a high-gloss surface can better reflect light, making the color purity higher and the color more vivid. On the contrary, a low-gloss surface scatters light, causing the color to appear darker, softer, with relatively lower saturation and contrast.   Glossiness and color are interrelated in printed matter and jointly affect the appearance quality of the printed matter. High-gloss printed materials have a smoother surface, which can reflect more light and make the colors more vivid and bright. On the contrary, printed materials with low gloss have a rougher surface, a weaker ability to reflect light, and their colors appear rather dull.   Specifically, the influence of glossiness on the color of printed matter is mainly reflected in the following aspects: 1. Enhance color saturation: The surface of high-gloss printed matter can reduce the white light reflected from the first layer surface, thereby enhancing the color saturation and making the colors more vivid.   2. Affecting color lightness: Glossiness also affects the lightness of the colors in printed matter. The higher the glossiness, the less white light is reflected from the first layer surface, and the higher the lightness of the color. Conversely, the lower the glossiness, the more white light is reflected from the first layer surface, and the lower the lightness of the color.   3. Impact on color visual effect: Glossiness also affects people's visual perception of the color of printed matter. High-gloss printed materials have a smoother surface, which can create a better visual texture and make the colors more attractive.   To accurately measure the glossiness and color of printed matter and ensure product quality, professional measuring instruments and scientific measurement methods must be adopted. The DG60 series gloss meter from CHNSpec, with its compact and lightweight design, efficient measurement speed and precise data output, has become a key tool for quality control in the printing industry. TheCHNSpec DG60 series gloss meter can quickly and accurately obtain the gloss data of printed paper. Whether it is a high-gloss, semi-gloss or matte surface, precise measurement results can be obtained. With the help of real-time data feedback, printing manufacturers can promptly adjust process parameters to ensure that each batch of printed materials meets the predetermined gloss standards.   For the measurement of glossiness, before the measurement, it is necessary to ensure that the instrument has been calibrated and the measurement environment is stable, avoiding interference from external light and temperature. Place the measuring probe of the gloss meter vertically on the surface of the printed matter and read the displayed gloss value. To obtain accurate and reliable results, it is usually necessary to measure at multiple locations and calculate the average value.     The measurement of color usually employs a spectrophotometer. TheCHNSpec DS-700 series spectrophotometer can accurately measure the appearance color of printed materials and achieve digital management of the appearance of printed materials.     In conclusion, the glossiness and color of printed matter are interrelated and jointly affect the quality and visual effect of the printed matter. Through scientific and reasonable measurement methods, these two key factors can be effectively controlled and evaluated, providing high-quality products for the printing industry.  
Lastest company cases about What are the differences between hyperspectral cameras and ordinary cameras?
2025/07/09
What are the differences between hyperspectral cameras and ordinary cameras?
I. Differences in Working Principles The working principle of a camera The principle is simple and straightforward. It captures light through the lens, and after the light is focused by the lens, it is projected onto the image sensor. The pixels in the image sensor generate corresponding electrical signals based on the received light intensity. These electrical signals, after a series of processing and conversion, eventually form the image we see. Ordinary cameras usually only perceive and record light within the visible light range. Their focus mainly lies in the basic features of objects such as shape, color and texture, in order to present a clear picture that conforms to the visual habits of the human eye.     The working principle of hyperspectral cameras The principle is much more complex. It can not only capture the information of an object in the visible light region, but also simultaneously obtain spectral information in multiple bands such as near-infrared and mid-infrared. When a hyperspectral camera is in operation, it decomposes light into spectral components of different wavelengths and then images the light reflected or emitted by objects at each wavelength separately. This imaging method is similar to conducting a "spectral scan" on an object, which can obtain rich information about the object in different spectral bands. By analyzing these spectral information, we can gain a deep understanding of the physical and chemical properties of objects, and even identify their composition and structure.     Ii. Differences in Data Acquisition Capabilities In terms of data acquisition, there is a world of difference between ordinary cameras and hyperspectral cameras. Photos taken by ordinary cameras are usually two-dimensional images, with each pixel containing only limited information such as color and brightness. A common color photo usually has each pixel composed of three color channels: red, green and blue. Various colors are presented through the combination of these three channels. Although ordinary cameras can obtain photos with different effects by adjusting shooting parameters such as ISO, shutter speed, aperture, etc., generally speaking, the data dimensions they obtain are relatively low, mainly focusing on the visual presentation of the image.   Hyperspectral cameras can obtain high-dimensional data cubes. In addition to two-dimensional spatial information, it also contains one-dimensional spectral information. Each pixel in this data cube corresponds to a complete spectral curve, recording the reflection or emission characteristics of the object at different wavelengths. This high-dimensional data provides extremely rich information resources for subsequent analysis and processing. For instance, in the agricultural sector, by analyzing the spectral features in hyperspectral images, one can accurately determine the growth status of crops, the situation of pests and diseases, as well as soil fertility and other information. In environmental monitoring, hyperspectral cameras can detect the components and concentrations of pollutants in water bodies, as well as changes in gas components in the atmosphere, etc.   Iii. Differences in application fields Due to the differences in working principles and data acquisition capabilities, hyperspectral cameras and ordinary cameras also have their own focuses in application fields.   Ordinary cameras are widely used in various aspects of daily life, such as photography enthusiasts capturing beautiful moments, news media taking news pictures, and commercial photography for product promotion, etc. It plays a significant role in scenarios such as social media, tourism, and family memorials, mainly meeting people's demands for visual aesthetics and documenting their lives. In addition, ordinary cameras also have certain applications in some basic scientific research fields, such as the observation of macroscopic biological forms in biology and the recording of simple experimental phenomena in physics.   Hyperspectral cameras are mainly applied in professional scientific research, industrial and military fields. In terms of scientific research, it provides powerful tools for the study of disciplines such as astronomy, geology and ecology. For instance, astronomers can use hyperspectral cameras to analyze the spectral characteristics of celestial bodies, thereby understanding their chemical composition and physical state. Geologists can identify different rock types and mineral resources through hyperspectral images. In the industrial field, hyperspectral cameras can be used for product quality inspection, food component analysis, material identification, etc. For instance, in the food processing industry, it can detect impurities, moisture content and nutritional components in food, ensuring the quality and safety of food. In the military field, hyperspectral cameras can be used for tasks such as target reconnaissance, camouflage recognition, and environmental monitoring. They can identify hidden targets through camouflage materials, providing important intelligence support for military decision-making.   Iv. Characteristics of Imaging Effects In terms of imaging effect, ordinary cameras pursue visual effects with bright colors, high contrast and good clarity to meet people's appreciation needs for beautiful pictures. Ordinary cameras strive to present realistic and vivid scenes in photos by optimizing the optical performance of lenses, image sensor technology and image processing algorithms, making the colors and details of objects more realistic.   The imaging effect of hyperspectral cameras focuses more on the accuracy and completeness of spectral information. The images it captures may not be visually as bright and eye-catching as ordinary photos, but they contain rich inner information. Each pixel in a hyperspectral image represents the spectral response of an object at a specific wavelength. By analyzing these spectral data, various characteristics of the object can be obtained. For instance, in hyperspectral images, different substances may exhibit distinct spectral characteristic curves. Even if they look very similar in appearance, they can still be accurately distinguished through spectral analysis. This imaging effect is of crucial significance for application scenarios that require precise identification and analysis of object components.     V. Equipment Cost and Complexity The technical complexity of hyperspectral cameras determines that they are far more expensive in terms of equipment cost and operational difficulty than ordinary cameras. The research and development of hyperspectral cameras involves advanced technologies from multiple fields such as optics, spectroscopy, electronics, and signal processing. Its manufacturing process requires the use of high-precision optical components and advanced detectors, and the cost of these parts is relatively high. In addition, to ensure that hyperspectral cameras can accurately obtain and process spectral information, they also need to be equipped with professional software and algorithms, which further increases their research and development and production costs.   In contrast, the technology of ordinary cameras has become relatively mature, and the market competition is fierce. Their manufacturing costs are relatively low, and the prices are also more affordable. The operation of a regular camera is relatively simple. Users only need to master some basic shooting skills to easily get started with it. The operation of hyperspectral cameras requires professional knowledge and skills. Operators need to understand the basic principles of spectroscopy and related data processing methods in order to fully leverage their advantages and obtain accurate and valuable information.
Lastest company cases about How to use a colorimeter to detect the color difference of coatings
2025/07/01
How to use a colorimeter to detect the color difference of coatings
In industrial production and daily life, the accuracy of color is becoming increasingly important. Whether it is automobile manufacturing, cosmetic production, or home decoration, the accuracy of color will affect the quality of the product and its market acceptance. To ensure the accuracy of colors, many industries have begun to use colorimeters to detect color differences. This article will introduce how to use a colorimeter to detect whether there is a color difference in the paint color.   I. Working Principle of Colorimeter A colorimeter is an instrument that assesses color differences by measuring the color brightness, saturation and hue of an object's surface. It can convert the color of an object into numerical values, and then calculate these values against the standard color values to obtain the color difference. A colorimeter is usually composed of a light source, a receiver and a processor.   Ii. Steps for Using a Colorimeter 1. Sample preparation     Select representative paint samples and apply them evenly on the cardstock, ensuring the surface of the samples is smooth to avoid deviations when light is reflected on the surface. Place it in a cool place to dry. Avoid sticking and contaminating the instrument, which may affect the measurement results.   2.Measurement stage   Place the colorimeter on the surface of the sample and adjust the Angle so that the light source shines perpendicularly on the sample. Then, press the measurement key, and the colorimeter will automatically measure the color of the sample and obtain the data. Usually, a colorimeter outputs three values: L, A and b. L represents the color brightness, a represents the red-green value, and b represents the yellow-blue value.     3.Data Analysis   Compare the data obtained by the colorimeter with the standard color data to calculate the color difference. Generally speaking, the smaller the color difference value, the closer the color is to the standard color. Commonly used color difference formulas include ΔEab, ΔE00, etc.     4.Result Report   Evaluate the qualification of the sample based on the calculated color difference value. If the color difference value is within an acceptable range, it indicates that the color of the coating meets the requirements. If the color difference value exceeds the acceptable range, the formula of the sample can be adjusted according to the data prompt of the colorimeter, and then a sample that meets the requirements can be obtained. The range value of whether the assessment is qualified or not can be set by the system itself.   Iii. Precautions 1,Keep the instrument clean: The colorimeter needs to be cleaned and maintained both before and after use to extend its service life. 2.Correct operation: Before use, carefully read the user manual and follow the operation steps for measurement. 3.Calibration: Before use, it is necessary to check whether the instrument has been calibrated to ensure the accuracy of the measurement results.      
Lastest company cases about How does the color haze meter THC-100 measure the spectral transmittance curve of AG glass
2025/06/26
How does the color haze meter THC-100 measure the spectral transmittance curve of AG glass
The Color Spectrum Color haze meter THC-100 is a professional measurement tool, focusing on the detection of multiple indicators of transparent materials, semi-transparent materials and liquids. It can accurately measure haze, transmittance, color, color difference, spectral transmittance, platinum-cobalt chromaticity, etc. Its unique full-spectrum LED light source and spectral sensor design make it perform exceptionally well. It is equipped with two test apertures of 21mm and 7mm, which can meet different measurement requirements. The operation is extremely simple and the measurement results are presented instantly. It can store massive amounts of data on a single machine and be connected to computer software to easily print test reports, providing great convenience for the detection and analysis of various materials and liquids.   The following will introduce how to measure the spectral transmittance curve of AG glass using the THC-100 color haze meter.   Step 1: Calibration Calibrate the instrument's test port 100% by pointing it towards the air.     Step 2: Set the indicators to be measured Open "Settings" → "Display" → "Graphics" → "Transmittance Curve", and click "Apply".       Step 3: Measure the AG glass sample Place the standard AG glass sample on the test port, click "Measure", and you can obtain the spectral transmittance curve and the transmittance values at intervals of 10nm from 400 to 700nm.         The above is the operation process of measuring the spectral transmittance curve of AG glass with the color haze meter THC-100.      
Lastest company cases about Haze meter: The eye of quality in the plastic industry
2025/06/21
Haze meter: The eye of quality in the plastic industry
In today's industrial landscape, plastic products are everywhere, ranging from ordinary daily necessities to high-end industrial components. With its rich and diverse properties and wide applicability, plastic has become a crucial material in modern manufacturing. In the plastic industry, haze meters are playing a crucial role and have become a key tool for ensuring product quality. Haze, as one of the important indicators for evaluating the optical properties of transparent or semi-transparent plastic materials, when light passes through the plastic material, due to various factors such as the internal structural characteristics of the material, possible impurities or surface conditions, it will cause light scattering and absorption, thereby making the passing light become hazy and unclear. The haze meter provides a quantitative evaluation basis for the optical performance of products in the plastic industry by precisely measuring the degree of light scattering.   For plastic product manufacturing enterprises, the application of haze meters holds significant implications in multiple aspects. Firstly, it has made significant contributions to ensuring the appearance quality of the product. In application fields with high requirements for appearance, such as optical lenses, display panels, etc., low-haze plastic materials can provide a clear and transparent visual experience, thereby enhancing the product's level and competitive strength. By conducting strict quality inspections with a haze meter, products that fail to meet the haze standards can be detected and eliminated in a timely manner, preventing substandard products from entering the market.   Secondly, the haze meter also plays a crucial role in the process of product development and quality control. When developing new plastic materials or improving production processes, haze meters can provide accurate optical performance data, helping engineers understand the characteristics and changing trends of materials, and thereby optimize formulas and process parameters to enhance the quality stability of products. In the production process, regular sampling and testing of products using haze meters can monitor production quality in real time, adjust production processes in a timely manner, and ensure that products always meet quality standards. Color haze Meter CS-700 (Measuring indicators: color, color difference, haze, transmittance, spectral transmittance) In addition, the haze meter also provides strong support for the standardization construction and quality certification of the plastic industry. Numerous industry standards and quality certification systems have clear regulations on the haze of plastic materials. The measurement results of haze meters can serve as an important reference for determining whether the products meet the standards. By using haze meters for detection, enterprises can make their products more easily recognized by the market, enhancing their credibility and competitiveness.   With the continuous advancement of technology, the performance of haze meters is also constantly upgrading. Modern haze meters feature high precision, high stability and easy operation, which can meet the actual needs of plastic enterprises of different scales. Meanwhile, some advanced haze meters also have data storage, analysis and transmission functions, which can be seamlessly integrated with the quality management system of enterprises, improving the efficiency and informatization level of quality management.   In conclusion, the haze meter holds an irreplaceable position in the plastic industry. It is not only a loyal guardian of product quality, but also an important driving force for the continuous development and progress of the plastic industry. In the future, as the plastic industry's requirements for product quality continue to rise, the application of haze meters will surely become more extensive and in-depth, continuing to contribute strongly to the vigorous development of the plastic industry.
Lastest company cases about Multispectral camera for Agriculture: Multispectral applications
2025/03/07
Multispectral camera for Agriculture: Multispectral applications
Multispectral technology, with its unique detection and analysis capabilities, has become a key force in achieving breakthroughs and innovations in many fields. This technology decomposes full-band or wide-band optical signals into multiple narrowband beams and images them respectively on corresponding detectors to obtain rich spectral information, allowing us to gain insight into details that are difficult to detect with the naked eye. From the perspective of detection accuracy, a single spectrum is like seeing with a single eye, with limited information, while multispectrum is like having multiple pairs of "eyes" for perception, which can capture light signals in different bands. So, how does multispectral technology realize these magical applications? Let's dig deeper together.   1. Principles and characteristics of multispectral technology In the process of agricultural modernization, multispectral technology is the most widely used in agricultural applications. The camera mounted on the multispectral drone can quickly scan vast farmland and accurately sense key information such as nitrogen content, chlorophyll content and moisture content of crops. Through these data, agricultural experts and practitioners can accurately analyze the growth status of crops, make accurate agricultural decisions based on the analysis results, and achieve precise variable fertilization. This not only reduces the waste of fertilizers and production costs, but also effectively improves the yield and quality of crops. When disaster strikes, multispectral drones can also capture abnormal changes in crops in a timely manner to protect agricultural production. The following is a real picture of the application of Caipu Technology's multispectral camera in the agricultural field. 2. Application of multispectral technology in agriculture In the process of agricultural modernization, multispectral technology is the most widely used in agricultural applications. The camera mounted on the multispectral drone can quickly scan vast farmland and accurately sense key information such as nitrogen content, chlorophyll content and moisture content of crops. Through these data, agricultural experts and practitioners can accurately analyze the growth status of crops, make accurate agricultural decisions based on the analysis results, and achieve precise variable fertilization. This not only reduces the waste of fertilizers and production costs, but also effectively improves the yield and quality of crops. When disaster strikes, multispectral drones can also capture abnormal changes in crops in a timely manner to protect agricultural production. The following is a real picture of the application of Caipu Technology's multispectral camera in the agricultural field. 3. Application of multispectral technology in the field of security monitoring In the field of security monitoring, multispectral technology has brought a qualitative leap to the monitoring system. Traditional monitoring equipment can often only capture image information within the visible light range, while multispectral monitoring equipment can not only perceive visible light, but also identify infrared and ultraviolet light, thereby obtaining more environmental information. At night or under low-light conditions, multispectral cameras can use infrared light to shoot and clearly present surveillance images; when detecting certain special substances or identifying camouflage, the application of ultraviolet light can play a key role, greatly improving the accuracy and reliability of security monitoring. 4. Potential applications of multispectral technology in the medical field In the medical field, multispectral technology also shows great potential. By performing multispectral imaging analysis on human tissues or diseased areas, doctors can obtain more comprehensive and in-depth physiological and pathological information. Taking skin cancer detection as an example, multispectral imaging technology can help doctors more accurately define the boundaries of lesions and determine the nature of lesions, providing a strong basis for early diagnosis and formulation of treatment plans. It is expected to increase the cure rate of the disease and improve the quality of life of patients. 5. Future Prospects of Multispectral Technology With the continuous advancement of science and technology and the in-depth application of multispectral technology, the application prospects of multispectral will become increasingly broad, promoting the development of various industries in the direction of intelligence and precision. Industry pioneers like Color Spectrum Technology are also constantly researching and applying multispectral technology. Its newly launched multispectral cameras, including FS-500, FS-600and FS-620, all have high resolution, high precision and powerful spectral analysis capabilities, which can accurately detect the growth status of crops and help intelligent and precise agricultural planting. I believe that in the future, multispectral technology will continue to bring more surprises and changes to our lives, making life better.        
Event
Our Latest News
Lastest company news about Which brand of hyperspectral camera is recommended for textile classification?
Which brand of hyperspectral camera is recommended for textile classification?
In the wave of intelligent upgrading of the textile industry, hyperspectral imaging technology has emerged as a shining star. With its unique feature of “image-spectrum integration,” it has become a core tool for precise textile classification. As the industry’s requirements for component identification, color consistency detection, and defect classification grow increasingly stringent, how to choose a hyperspectral device that can adapt to complex scenarios has become the focus of many enterprises and research institutions.   Among many brands, CHNSPEC stands out. As a leader in the domestic hyperspectral field, CHNSPEC has built a complete and advanced technical system through relentless independent R&D. Its products have demonstrated remarkable advantages in textile classification scenarios.   I. Outstanding Spectral Precision and Hardware Innovation The CHNSPEC FS1X series hyperspectral camera can be regarded as a model in the industry. It covers the full spectral range of 400–1700nm, with resolution as high as 2.5nm in the visible/near-infrared band. Such high resolution enables it to accurately identify the unique spectral characteristics of different fibers at specific bands.   In addition, CHNSPEC’s original synchronous measurement structure—for example, using a stepper motor to control baffle switching—achieves the powerful function of simultaneously obtaining SCI (including specular reflection) and SCE (excluding specular reflection) data. This innovative design is of great significance, as it can accurately quantify the influence of surface gloss on color measurement, ensuring highly consistent results even when testing fabrics with different gloss levels.   II. High-Speed Imaging and Intelligent Processing to Meet Diverse Needs (1) A Powerful Assistant for Online Production Line Detection To meet the fast-paced production demands of the textile industry, CHNSPEC provides highly targeted differentiated solutions. For example, the FS1X series achieves full-spectrum imaging speeds of up to 128Hz and supports multi-ROI functions. This means that on a fast-moving conveyor belt, it can act like a tireless guardian, accurately identifying stains, color fastness differences, and other defects in real time, safeguarding product quality.   (2) A Precise Tool for Component Analysis and Blend Ratio Calculation In component analysis, the FS-17 model (900–1700nm, 6nm resolution), combined with a near-infrared spectral library, functions like an experienced “fiber detective.” It can easily distinguish natural fibers such as cotton, linen, and silk from synthetic fibers such as polyester and acrylic. Through in-depth analysis of spectral data, it can accurately calculate blending ratios, providing key data support for textile quality control and R&D innovation.   (3) A Reliable Partner for Research-Level Fine Analysis For researchers, the FS-2X series (1920×1920 pixels, 128Hz full-spectrum) is undoubtedly a powerful assistant. It can support the extraction of spectral characteristics of single yarns, making it possible to study fiber properties in depth. A team at Beijing Forestry University skillfully used this equipment to successfully analyze the spectral response patterns of different fibers during dyeing, providing a solid theoretical basis for optimizing dye formulations.   III. Localized Services and Scenario Adaptation: More Attentive and Professional Compared with international brands, CHNSPEC’s advantage in localized services is clear. It can provide full-chain services from hardware customization, such as textile-specific optical filters, to algorithm optimization, such as spectral models for blended fibers.   For the diverse and complex production lines of textile clusters in southern China, CHNSPEC launched the FS1X-UCR LiDAR-hyperspectral integrated system, which is particularly ingenious. It can simultaneously acquire 3D structural and spectral data, enabling stereoscopic defect modeling and dynamic tracking, perfectly adapting to complex production environments and solving real industrial challenges.   In textile classification scenarios, CHNSPEC hyperspectral cameras have already formed a mature and efficient application paradigm: (1) Routine sorting: Using the FS-10 UAV-mounted system (400–1000nm, 2.5nm resolution), textile classification by composition and color can be performed quickly via scaled imaging, greatly improving sorting efficiency. (2)Scientific research monitoring: The FS-2X series, combined with laboratory analysis software, provides strong support for studying the correlation between fiber spectral responses and dyeing processes, helping researchers explore unknown areas in textile research.   In benchmarking against international brands, CHNSPEC hyperspectral cameras also demonstrate significant differentiated advantages: (1) Technical parameters: The FS-23 model’s spectral resolution (2.5nm) and imaging speed (128Hz) are on par with imported brands, but at a lower cost, truly achieving high performance at low price. (2)Service system: CHNSPEC offers 24/7 technical support and customized model development services, with a response speed far superior to imported brands, giving users peace of mind. (3) Ecological compatibility: The devices adopt an IP65 protection design, ensuring stable operation in extreme environments. Whether in high-temperature, high-humidity dyeing workshops or cold, dry storage facilities, they can operate with ease.   The key to textile classification lies in decoding material and color through precise spectral data. With its full-spectrum coverage, high-speed imaging, and intelligent processing capabilities, CHNSPEC provides solid and reliable technical support for the textile industry. Its combination of UAV-mounted systems, portable devices, and laboratory-level analysis platforms not only meets the efficiency demands of large-scale production lines but also supports research-grade fine analysis. For domestic textile enterprises, quality inspection agencies, and research institutions, CHNSPEC hyperspectral cameras are undoubtedly the best choice for achieving intelligent textile classification and sustainable management. Choosing CHNSPEC means choosing a more efficient, more accurate, and smarter textile classification solution!
Lastest company news about Which Hyperspectral Camera is Best for Cell Activity Monitoring?
Which Hyperspectral Camera is Best for Cell Activity Monitoring?
In biomedical research, the accuracy of cell activity monitoring directly depends on a hyperspectral camera’s ability to capture biochemical features. From routine 2D cell cultures to complex 3D spheroid studies, choosing a hyperspectral camera tailored to the research scenario is critical.As a leading domestic brand, CHNSPEC has established unique advantages in spectral precision, imaging efficiency, and application adaptability with its FigSpec® Series. This makes it a cost-effective choice for cell activity monitoring. I. Technical Challenges in Cell Activity Monitoring and CHNSPEC’s Targeted Solutions Cell activity monitoring faces three core challenges: precise capture of weak spectral signals, stability during long-term dynamic monitoring, and spectral band adaptability to different culture models. CHNSPEC achieves breakthroughs through hardware innovation and algorithm optimization:   Spectral Resolution: The FigSpec® FS-23 achieves an ultra-high resolution of 2.5nm (400–1000nm), enabling clear distinction of spectral peaks such as nucleic acids (260nm) and mitochondrial cytochrome oxidase (600–650nm) during apoptosis. This performance approaches the research-grade standards of leading international brands like Thermo Fisher. For complex models such as 3D spheroids or organoids, the FS-25 extends into the 900–1700nm SWIR band, enabling visualization of spatial activity distribution within cell aggregates.   Low-Noise Imaging: Equipped with low-dark-current CMOS sensors and ≤0.5% stray light control, CHNSPEC outperforms industry averages. This minimizes light damage from long exposures, making it especially suitable for sensitive cell types such as stem cells.   Imaging Efficiency: The FS-23 achieves 5-second rapid imaging, nearly 3× faster than the Olympus OLS5000 system. This high throughput is particularly advantageous for drug screening, enabling both large-scale data collection and reduced cellular stress during monitoring.   II. Core Technical Advantages of the CHNSPEC FigSpec Series The CHNSPEC FigSpec FS2X series adopts a modular design to meet the monitoring needs of different cell models: Multi-band precise coverage is the outstanding feature of this series. The FS-22/23 models (400–1000nm) cover the characteristic spectra of key substances such as cytochromes and hemoglobin, making them very suitable for routine live-cell dynamic monitoring; the FS-25 model (900–1700nm) is optimized for deep tissue imaging, with its InGaAs detector maintaining 60% transmission efficiency at the 1500nm band, enabling stratified activity analysis of 3D cell spheroids. With an ultra-high sampling density of 512 spectral channels, even subtle biochemical variation signals will not be missed.   Seamless integration with microscopy systems reflects CHNSPEC’s scenario-driven design concept. All models adopt a standard C-mount, directly compatible with mainstream objectives such as Olympus and Nikon, achieving cell-level spatial resolution without the need for additional adapters. The auxiliary viewfinder camera allows researchers to quickly locate regions of interest (ROI), significantly improving experimental efficiency.   Intelligent analysis software lowers the threshold for applying hyperspectral technology. The built-in “Cell Activity Analysis Module” can automatically unmix spectral data and directly output quantitative indicators such as viability and proliferation rates, avoiding the secondary development costs of general-purpose software. The software also supports compatibility with research tools, facilitating in-depth data mining and the generation of publication-ready charts.   III. Brand Comparisons: CHNSPEC’s Differentiated Value In the cell monitoring scenario, CHNSPEC has three major advantages over international brands and other domestic brands: 1. FigSpec FS-23: Spectral range 400-1000nm, 2.5nm resolution, 5-second imaging, integrated system with activity analysis, high resolution, recommendation index ★★★★★, score 9.9; 2. Thermo Fisher DXR3xi: Spectral range 400-900nm, 5nm resolution, 20-second imaging, integrated system, requires professional operation, recommendation index ★★★, score 8.6. 3. Olympus OLS5000: Spectral range 400-900nm, 3nm resolution, 15-second imaging, high spatial resolution, fixed band, recommendation index ★★★, score 8.2; 4. Hikvision MV-CHS010, 400-1000nm, 8nm resolution, 10-second imaging, basic imaging, no dedicated analysis module, recommendation index ★★★, score 8.1.   In terms of the balance between performance and cost, CHNSPEC has achieved comparable core indicators at a price that is one-third to half of that of international brands. Its 600:1 signal-to-noise ratio ensures that the subtle spectral changes during cell apoptosis can be captured, while the built-in battery-powered design increases the flexibility of use in special environments such as laminar flow hoods. For special requirements such as anaerobic incubator adaptation, CHNSPEC can provide customized shell modification completed within 2-3 weeks, which is particularly crucial for innovative experiments.   IV. Model Selection Recommendations: Matching the Right Model to Your Scenario According to the specific needs of cell monitoring, CHNSPEC provides a clear selection path: For basic academic research, the FS-22 model (400–1000nm, 5nm resolution) offers high cost-effectiveness and can meet the requirements of teaching and routine experiments. Its 1920×1920 image resolution can simultaneously accommodate both single-cell detail and population distribution observation.   For pharmaceutical drug screening scenarios, the FS-23 model is recommended. Its ultra-high spectral resolution of 2.5nm can accurately distinguish the differences in apoptosis stages of cells under drug action. Combined with 5-second rapid imaging capability, it enables high-throughput activity detection, with daily data output reaching several times that of traditional systems.   For 3D cell spheroid or organoid research, the FS-25 short-wave near-infrared model is the only choice. The 900–1700nm band can penetrate the surface of cell spheroids and capture metabolic signals of deep active cells, while its 6nm spectral resolution is sufficient to distinguish biochemical differences between hypoxic regions and normal active regions.   Empirical verification is the key step in model selection. It is recommended to contact CHNSPEC to request sample testing, using target cell samples to verify two core indicators: first, the spectral distinction between active/apoptotic cells; second, the stability of signals during continuous imaging. CHNSPEC provides free on-site debugging services to ensure that the system achieves excellent performance in actual experimental environments.   V. Conclusion: CHNSPEC Redefines the Cost-Effectiveness Standard in Cell Monitoring In the field of cell activity monitoring, the CHNSPEC FigSpec series, with its combination of “precise spectroscopy + efficient imaging + scenario customization,” has broken the technological monopoly of imported brands. Its core advantage does not lie merely in parameters, but in its deep understanding of cell monitoring scenarios — from low-noise design that reduces cell photodamage to dedicated software that lowers the barrier to data analysis, every optimization directly addresses the real pain points of researchers.   For university laboratories with limited budgets but high research quality demands, CHNSPEC provides a choice without compromising performance; for pharmaceutical companies requiring high-throughput screening, its efficiency advantage can be directly translated into reduced R&D costs; and for cutting-edge research into 3D cell models, the short-wave near-infrared model opens up a new dimension of observation. At its essence, choosing a hyperspectral camera means choosing a technical solution that matches one’s own research needs, and CHNSPEC undoubtedly provides a highly competitive domestic alternative for cell activity monitoring.
Lastest company news about Technological Breakthrough Leading a Spectral Revolution: CHNSPEC FigSpec FS-2A Hyperspectral Imager Grand Launch.
Technological Breakthrough Leading a Spectral Revolution: CHNSPEC FigSpec FS-2A Hyperspectral Imager Grand Launch.
Amid the continuous evolution of spectral analysis technology, a hyperspectral imaging device that integrates innovative design with powerful performance has emerged. CHNSPEC introduces the FigSpec Series Full-Spectrum Hyperspectral Imager FS-2A, which precisely addresses the pain points of traditional technology and is quickly becoming the new choice for spectral applications across industries.   Conventional hyperspectral cameras often struggle with issues such as complex external push-broom scanning mechanisms and cumbersome focusing operations. The FS-2A fundamentally resolves these challenges. It adopts a high-diffraction-efficiency transmission grating spectroscopic module combined with a high-sensitivity area array camera, integrated with built-in scanning imaging and auxiliary camera technology, making operation simple and efficient. At the same time, the device can be directly integrated with imaging lenses using a standard C-mount, enabling rapid spectral image acquisition and significantly enhancing work efficiency.     In terms of core performance, the FS-2A demonstrates industry-leading capabilities. Its short-wave near-infrared spectral range covers 900–2500nm, with a spectral resolution better than 10nm and no fewer than 250 spectral channels, enabling the capture of subtle spectral variations of materials. With an image resolution of 640×640 and a 25mm focal length lens providing a 21.7° field of view, it ensures clear imaging with a broad perspective. In addition, the device employs a Stirling-cooled MCT detector with an effective bit depth of ≥14 bits, providing a solid guarantee for acquiring high-quality spectral data.   The FS-2A is designed for wide-ranging and in-depth applications: 1. In geological and mineral exploration, it accurately identifies mineral types and distribution through spectral features. 2. In precision agriculture and crop monitoring, it enables real-time analysis of crop growth conditions and pest infestations, supporting scientific cultivation. 3. In the cultural heritage sector, its non-contact detection capability allows detailed research into artifact materials and preservation conditions. 4. In military and security applications, its high-sensitivity spectral detection provides strong support for surveillance and safety.   Notably, the FS-2A is developed with independent intellectual property rights, reflecting CHNSPEC’s strong R&D strength in hyperspectral imaging technology. The device supports USB 3.0 interfaces, is compatible with multiple data formats including spe, hdr, and scp, and comes equipped with FIGSPEC CAM and FIGSPEC Studio software, offering a complete ecosystem for data acquisition and analysis. Its built-in battery power supply further enhances portability and operational flexibility.   From laboratory research to industrial inspection, from agricultural production to cultural preservation, the FigSpec® Full-Spectrum Hyperspectral Imager FS-2A embodies the philosophy of “Observing the World with Spectra”, empowering a wide range of industries. With continued technological adoption, it is set to create value across more fields and open a new chapter in spectral applications.
Lastest company news about Selection and Application of spectrophotometer in the Textile Printing and Dyeing Industry: A full-chain solution from yarn dyeing to garment quality control
Selection and Application of spectrophotometer in the Textile Printing and Dyeing Industry: A full-chain solution from yarn dyeing to garment quality control
In the textile printing and dyeing industry, precise color control is the key to ensuring product quality, running through the entire process from yarn dyeing to garment quality control. As a core tool for color measurement, the reasonable selection and application of colorimeters are crucial for enhancing the competitiveness of products. The series of colorimeters launched by CHNSpec Technology meet the diverse needs of various industries with their different features.   I. Yarn dyeing process: Precise measurement lays the foundation     1. Instrument selection: Choose the CHNSpec DS-36D benchtop spectrophotometer with reference grade. It adopts a dual optical path design of differential spectroscopy engine and nanoscale grating, which can effectively reduce the interference of external factors and ensure stable and accurate measurement results.   2. Measurement advantage: During the yarn dyeing process, different batches of yarn have strict requirements for color consistency. The DS-36D can measure the yarn color quickly and accurately, and obtain detailed color data, such as CIE Lab, XYZ and other color space parameters. For instance, when producing a batch of blue yarn, the standard color sample is first measured with DS-36D to obtain precise color data. Then, measure the dyed yarn. By comparing the two sets of data, the color difference situation can be clearly known.   3. Production Application: If the measurement results show color differences, dyeing workers can precisely adjust the dye formula based on the data provided by DS-36D. For instance, if the color is too light, the proportion of dye can be appropriately increased. If the hue is off, the mixing ratio of different dyes can be adjusted. At the same time, it can also optimize process parameters such as dyeing time and temperature, thereby effectively controlling the color of the yarn, reducing the rate of defective products, and ensuring that the color of the entire batch of yarn is uniform and consistent.   II. Fabric printing and dyeing stage: Efficient measurement ensures quality     1. Instrument recommendation: CHNSpec CS-820P benchtop spectrophotometer is the ideal choice for this stage. It is equipped with a 7-inch TFT true-color capacitive touch screen and an android operating system. The operation interface is intuitive and friendly, reducing the learning cost for operators.   2. Functional Features: The fabric is rich in printing and dyeing patterns and colors. The CS-820P has a rapid measurement function, which can measure the colors of different printing and dyeing areas in a short time. In large-scale production, color deviations can be detected in a timely manner through real-time measurement. Meanwhile, it supports data storage, export and wireless transmission functions, enabling the rapid transfer of measurement data to the production management system.   3. Practical operation: Taking the production of printed fabrics as an example, when it is found that the local color of a certain piece of fabric differs from the standard color, the CS-820P can be immediately used for measurement to obtain the color difference data. Based on the data, operators can promptly adjust the parameters of the printing and dyeing equipment, such as increasing or decreasing the dye injection volume and adjusting the printing and dyeing speed, to ensure that the color of the fabric produced subsequently meets the standards. In addition, through the analysis of the measurement data, the color change patterns of different batches of fabrics can also be summarized, providing a reference for optimizing the production process.   III. Quality Control of ready-made Garments: Multi-scenario measurement ensures quality     1. Applicable instrument: CHNSpec DS-812N benchtop liquid colorimeter is suitable for various scenarios in garment quality control. This instrument is equipped with over 30 chromaticity indicators and can meet the various chromaticity measurement requirements related to liquids in the garment production process.   2. Specific application: In garment production, when liquid dye color matching is involved, DS-812N can precisely measure the chromaticity of liquid dyes, assisting technicians in blending colors that meet the requirements. In terms of assessing the color fastness of clothing, for instance, for garments that have undergone washing or special treatment, the DS-812N can be used to measure the color change of the soaking solution before and after treatment. If the color of the soaking solution changes significantly, it indicates that there is a problem with the color fastness of the clothing and it needs to be reprocessed.   3. Performance advantages: The intelligent zero-point calibration function of DS-812N ensures measurement accuracy, with the minimum liquid addition reduced to 1ml, significantly minimizing sample loss. Meanwhile, it can adapt to various cuvette specifications and be flexibly selected according to actual measurement requirements, facilitating and enabling the measurement work to be completed conveniently and quickly.   These color difference meters from CHNSpec Technology, with their unique performance and functions, provide reliable color measurement solutions for the entire chain of the textile printing and dyeing industry. The rational selection of these instruments by enterprises can help improve product quality and gain an advantageous position in market competition.
Lastest company news about CHNSpec DS-700D Spectrophotometer: An innovator in precise color measurement
CHNSpec DS-700D Spectrophotometer: An innovator in precise color measurement
In the field of color measurement, accuracy and reliability are eternal pursuits. As a highly regarded brand in the industry, CHNSpec has launched the DS-700D spectrophotometer, which has become a benchmark product in the field of color measurement with its advanced technical concepts and innovative design. It not only inherits the advantages of traditional spectrophotometers, but also achieves breakthroughs in multiple key technical dimensions, providing more efficient and accurate color solutions for industrial production, scientific research testing and other fields.     I. Brand Strength: The technological accumulation of CHNSpec CHNSpec has always been committed to the research and development and innovation of optical measurement technology. Over the years, it has accumulated profound technical expertise in the field of color measurement. The brand has gathered a group of professional R&D teams in optics, electronics and algorithms, constantly exploring the cutting-edge technologies in the industry, and is committed to providing users with high-quality measuring instruments. From product design to production process, CHNSpec has always adhered to a rigorous attitude, strictly controlling every link to ensure that each instrument has outstanding performance and stable quality. The launch of the DS-700D spectrophotometer is a concentrated demonstration of CHNSpec's technical strength. It integrates the brand's years of research and development experience and innovative achievements, bringing users a more superior measurement experience.   II. Core Advantages: Technical Highlights of DS-700D (1) Advanced measurement structure and correction model The DS-700D spectrophotometer adopts an innovative measurement structure based on D/8 illumination conditions, which is compatible with two geometric conditions including specular reflection light (SCI) and removal of specular reflection light (SCE). This design inspiration comes from the in-depth research on gloss correction models in the optical field. By simultaneously measuring the data of the sample under SCI and SCE conditions, the gloss data of the sample surface can be accurately obtained. As relevant research has pointed out, measurement deviations can occur due to the size differences of optical traps in different instrument structures. However, the DS-700D, through its built-in gloss correction model, dynamically corrects the SCE measurement results based on the gloss data of the material being measured, effectively reducing the inter-instrument differences caused by the structural variations of the instruments. This innovative design enables the instrument to maintain excellent measurement consistency when measuring samples with different surface characteristics such as high gloss and semi-gloss, significantly enhancing the reliability of the data.   (2) High-precision spectral measurement capability The instrument is equipped with a high-resolution spectral sensor and a high-quality optical system, capable of achieving precise spectral collection within the visible light range (400-700nm). Its spectral resolution reaches 10nm, which can precisely capture the changes in light intensity at different wavelengths, providing a solid guarantee for the accuracy of color data. In actual measurement, the DS-700D can quickly generate the spectral reflection curve of the sample. By comparing it with the standard color card or database, it can accurately determine the color characteristics of the sample. Whether it is for color matching in the printing industry or color difference detection in fields such as coatings and textiles, its high-precision measurement capability can meet the strict requirements of professional users.   (3) Intelligent operation and data management The DS-700D is equipped with a user-friendly operation interface and an intelligent data management system. The instrument is equipped with a clear color display screen, allowing users to directly view measurement data, spectral curves and other information. Through the built-in Bluetooth or USB interface, data can be easily transferred to a computer or mobile device. Combined with dedicated data analysis software, functions such as data storage, analysis, and report generation can be realized. In addition, the instrument also supports custom measurement parameters. Users can set appropriate lighting conditions, observation angles and other parameters according to different measurement scenarios, further enhancing the convenience and flexibility of operation.   III. Application Scenarios: Precise Adaptation in Multiple fields (1) Quality control in industrial production In industrial fields such as automotive manufacturing, electronic equipment, and coatings, the consistency of color is an important indicator of product quality. The DS-700D spectrophotometer can be used in raw material inspection, production process monitoring, and finished product testing, etc., to ensure that the product color meets the design standards. For instance, in an automotive painting production line, by measuring the color data of the body coating in real time, the spraying process can be adjusted promptly, avoiding rework and waste caused by color differences.     (2) Scientific Research and Laboratory Testing Research institutions and laboratories have extremely high requirements for the accuracy and reliability of color measurement. With its advanced technical parameters and stable performance, the DS-700D has become an ideal tool for research in fields such as optics, materials science, and color science. Researchers can use the instrument to conduct experiments such as color characteristic analysis and gloss influence research, providing accurate data support for scientific research projects.   (3) Color Management and Design In industries such as printing, packaging and advertising, the accurate reproduction of colors is the key. The DS-700D can help designers and printing manufacturers achieve precise color matching from design drafts to printed materials. By measuring the color data of the printed sample and comparing it with the design file, the printing parameters can be adjusted in a timely manner to ensure that the color effect of the final product is consistent with expectations.   IV. CHNSpec Technology leads the new future of Color measurement CHNSpec DS-700D spectrophotometer, with its outstanding brand endorsement, advanced technological advantages and wide range of application scenarios, demonstrates strong competitiveness in the field of color measurement. It not only solves the problem of inter-instrument differences caused by structural variations in traditional measuring instruments, but also enhances operational efficiency through intelligent design, providing users with a better measurement experience. With the continuous improvement of the industry's requirements for color accuracy, DS-700D is expected to become the preferred tool for more professional users, leading the color measurement industry to a new height. Whether it is quality control in industrial production or in-depth research in scientific research laboratories, the CHNSpec DS-700D spectrophotometer will provide solid technical support for the development of the color field with its precise and reliable performance.
Lastest company news about Technology empowers ecological monitoring, and the CHNSpec hyperspectral unmanned aerial vehicle nest system makes a stunning debut
Technology empowers ecological monitoring, and the CHNSpec hyperspectral unmanned aerial vehicle nest system makes a stunning debut
Today, with the rapid development of science and technology, the field of ecological environment monitoring has also witnessed significant changes. Recently, the hyperspectral unmanned aerial vehicle nest system launched by CHNSpec Technology has attracted the attention of many industry insiders with its innovative technology and powerful functions, becoming a new focus in the field of ecological monitoring.   The birth of this hyperspectral unmanned aerial vehicle (UAV) nest system is the result of CHNSpec Technology's continuous exploration and innovation in spectral technology and the UAV field over the years. Its emergence has completely transformed the traditional model of ecological environment monitoring and brought brand-new development opportunities to this field.     From the perspective of appearance, the unmanned aerial vehicle (UAV) automatic hangar has a simple and elegant design, yet it is equipped with powerful functions. It is not only a "warm home" for drones, but also the core hub for the entire system to achieve automated operations. When the drone returns after completing its monitoring mission, the hangar can automatically identify and guide it to land precisely, and then quickly activate the automatic battery swapping function to ensure that the drone can regain its "energy" in the shortest time and be ready to set out again to carry out the mission at any time. This efficient operation process has greatly enhanced the continuity and efficiency of monitoring work.   The hyperspectral camera, as the "eyes" of the system, has an even more astonishing performance. The CHNSpec FS60C hyperspectral camera can capture more abundant and detailed spectral information than ordinary cameras. It is like a "spectral detective", capable of uncovering the secrets hidden behind the spectrum from seemingly ordinary natural landscapes. Whether it is the slightest change in pollutants in water bodies or the subtle physiological state differences of vegetation leaves, none can escape its "sharp eyes".   Drones, as the "flying messengers" of the system, carry hyperspectral cameras and shuttle through the sky. The DJI M350 RTK drone, with its outstanding flight performance, can fly stably in various complex weather conditions and terrain environments. It can fly autonomously to the target area along the preset route and collect high-precision spectral data. During the flight, intelligent path planning and dynamic obstacle avoidance functions provide protection for it, enabling it to flexibly avoid obstacles and ensuring the safe and smooth progress of data collection work.     In practical applications, the CHNSpec hyperspectral unmanned aerial vehicle nest system has demonstrated its powerful capabilities. In the field of agriculture, it is like a "smart agronomist". Through hyperspectral monitoring of farmland, the system can quickly analyze the growth status of crops. For instance, by monitoring vegetation indices, it can be determined whether crops lack nutrients or are attacked by pests and diseases. Once problems are detected, the system can also provide farmers with precise suggestions on fertilization, irrigation and pest control based on the built-in algorithms, helping them achieve scientific planting and increase the yield and quality of crops.   In terms of forestry monitoring, this system has transformed into a "forest guardian". It can conduct rapid inspections of large areas of forests. By analyzing the spectral characteristics of trees, it can promptly detect problems such as pests and diseases, and fire hazards in the forest. In the monitoring of a certain forest area, the system, through the analysis of the spectral data of trees, detected in advance an area with potential risks of pine wood nematode disease. Relevant departments promptly took measures, effectively curbing the spread of pests and diseases and protecting forest resources.       In urban ecological environment monitoring, the CHNSpec hyperspectral unmanned aerial vehicle nest system also plays a significant role. It can conduct all-round monitoring of the city's water bodies, green Spaces, atmosphere, etc. For instance, monitoring the water quality of urban rivers and assessing the ecological benefits of urban green Spaces can provide a scientific basis for the ecological environment planning and management of cities.   In addition to its application in specific fields, the CHNSpec hyperspectral unmanned aerial vehicle nest system also features a high degree of intelligence and scalability. The multiple deep learning algorithms built into the system enable it to continuously learn and adapt to different monitoring requirements. Users can independently import algorithm models based on actual application scenarios, conduct training and upgrades, thereby expanding the application scope and monitoring accuracy of the system. Meanwhile, the system supports the connection of third-party data for calibration, further enhancing the accuracy and reliability of the data.   As people's demands for the quality of the ecological environment continue to rise, the importance of ecological environment monitoring is becoming increasingly prominent. The hyperspectral unmanned aerial vehicle nest system launched by CHNSpec Technology, with its advanced technology, powerful functions and broad application prospects, has injected new vitality into the field of ecological environment monitoring. It is believed that in the future, this system will play an important role in more fields and contribute to protecting our green mountains and clear waters.
Lastest company news about Brand recommendation for Protable Spectroradiometer, CHNSpec FigSpec has been shortlisted
Brand recommendation for Protable Spectroradiometer, CHNSpec FigSpec has been shortlisted
Today, with the deep integration of remote sensing technology and precision agriculture, Protable Spectroradiometer, as the core tool for obtaining the spectral fingerprints of surface materials, is moving from the laboratory to the fields. Facing the complex and diverse demands of fieldwork, domestic manufacturers represented by FigSpec have launched handheld devices that combine high precision and portability through innovative design and technological breakthroughs, redefining the efficiency standards for ground object spectral measurement.   I. Technical Characteristics and Market Pattern of International Brands ASD FieldSpec: A brand under the American company Tianbao, it is renowned for its full-band coverage of 350-2500nm and ultra-high resolution of 0.5nm. It is widely used in NASA remote sensing projects. However, its price of nearly a million yuan and the weight of a 20kg device limit its popularity in the field.   SVC HR-1024i: A representative laboratory-grade device, it supports fiber optic probes and integrating sphere accessories, and holds an advantage in the field of material testing. However, it needs to be used in conjunction with a professional workstation, and the operation threshold is relatively high.   TriOS RAMSES: A pioneer of portable solutions in Germany, it has built-in GPS and storage functions and is suitable for Marine monitoring. However, its short-wave infrared coverage is insufficient (1000-1700nm), which limits its application in geological exploration.   II. Technological Breakthroughs of the FigSpec Protable Spectroradiometer As a domestic manufacturer that simultaneously masters the technology of micro spectral chips and system integration, FigSpec has launched the FS-9100/9200/9300 series, which has completely overturned the bulky image of traditional ground object spectrometers.   Full-band coverage: From 300-1100nm of FS-9100 to 300-2500nm of FS-9300, through self-developed dual-detector integration technology, it achieves full-spectrum coverage from visible light to short-wave infrared, breaking through the technical bottleneck of short-wave infrared (SWIR) for domestic equipment.   Portable design: The FS-9100 weighs only 2.3kg. It features a 5.5-inch touch screen and a 12-megapixel camera, supporting GPS positioning and real-time Angle display. It can be held with one hand to complete measurements in multiple scenarios such as vegetation canopy and water bodies.   Intelligent function innovation: Built-in JY60 gyroscope for ±180° tilt monitoring, combined with a laser positioning system to ensure consistent measurement angles. The FS-9300 supports contact handles and aiming pistol accessories, making it suitable for complex scenarios such as rock outcrops and soil profiles.     III. Scenario-based Solutions of CHNSpec FigSpec Precision agriculture: FS-9200 achieves an inversion error of less than 2.5% for crop nitrogen content through 300-1700nm spectral analysis, supports real-time generation of NDVI vegetation index maps in the field, and guides variable fertilization.   Ecological monitoring: In the Qinghai Lake ecological protection project, FS-9300 achieved dynamic monitoring of blue-green algae blooms through the inversion model of chlorophyll a in water bodies and combined with GPS trajectory recording, increasing the data collection efficiency by 40%.   Geological exploration: In the exploration of copper mines in Yunnan, the SWIR band (1000-2500nm) of FS-9300 successfully identified characteristic peaks of minerals such as malachite and azurite, reducing the cost of field sampling by 60%.   Dimension Traditional equipment The FigSpec series of CHNSpec Cost 800,000 to 1.5 million RMB accounts for only one third of the import price Response speed requires an external computer for processing Built-in Windows 11 system for real-time analysis Environmental adaptability requires an external computer for processing IP65 waterproof and dustproof Data compatibility Exclusive formats need to be converted by professional software Supports export in CSV/ASCII universal formats   The launch of the FigSpec Protable Spectroradiometer not only broke the price monopoly of imported equipment but also redefined the performance boundaries of portable spectrometers through technological innovation. In the future, with the deep integration of AI and Internet of Things (iot) technologies, CHNSpec FigSpec may become the "Chinese standard" in the global field of Protable Spectroradiometer.
Lastest company news about CHNSpec Technology's TH-07 series touch screen haze meter is officially launched - ushering in a new era of precise detection of transparent materials
CHNSpec Technology's TH-07 series touch screen haze meter is officially launched - ushering in a new era of precise detection of transparent materials
Today, with the rapid development of the precision manufacturing and optical materials industries, the haze and transmittance performance of transparent materials have become the core indicators for measuring product quality. Recently, CHNSpec Technology, relying on its years of accumulation in optical detection technology, officially launched the TH-07 series touch screen haze meter. This professional-grade testing equipment, with "precision, efficiency and intelligence" at its core, integrates multiple innovative technologies, redefines the measurement standards for haze/transmittance of transparent materials, and provides strong technical support for quality control in the industry.     I. Core Advantage: Establishing a benchmark for testing through technological innovation The TH-07 series haze meter has achieved a full-dimensional upgrade from optical principles to operational experience, with multiple core advantages directly addressing the pain points in industry detection:   Standard optical architecture, precise and reliable data Adopting the internationally recognized 0/d optical structure, it ensures the scientificity and consistency of measurement data from the source. The equipment fully complies with the haze standards of the three major systems, namely GB/T 2410, ASTM D 1003/1004, and ISO 13468/14782, covering the testing specification requirements of multiple regions and industries, ensuring that the testing results have credibility worldwide.   An extremely long lifespan and ultimate precision coexist Equipped with high-performance light sources, it has a service life of up to 5 years or 5 million tests, significantly reducing equipment maintenance costs and downtime losses. In terms of measurement accuracy, the mid-to-high-end model TH-07 in the series has a resolution of 0.01%, with a repeatability error of no more than 0.05%. Even the slightest differences in optical performance can be precisely captured, providing solid data support for high-precision material inspection.   Intelligent operation and massive storage are seamlessly integrated Equipped with a 7-inch IPS full-view LCD screen and capacitive touch screen, the operation is smooth and intuitive. You can quickly get started without professional training. A single machine can store 20,000 sets of test data. Combined with the standard HAZE QC PC management software, it supports one-click data export, automatic report generation and printing, easily achieving the full life cycle management of test data.   II. Technical Parameter Highlights: Series configuration meets diverse needs The TH-07 series includes three models: TH-05, TH-06, and TH-07, covering different scenario requirements through differentiated configurations   The light source adaptation is more flexible: TH-05 supports CIE-A and CIE-C light sources. TH-06 and TH-07 add CIE-D65 light sources on this basis, which can simulate the optical performance of materials under different lighting environments.   More comprehensive measurement standards: TH-05 focuses on haze and transmittance measurement under ASTM standards, while TH-06 and TH-07 support parallel testing under both ASTM and ISO standards, meeting the multi-standard production needs of multinational enterprises.   The detailed design is more considerate: All three models support the detection of samples with a thickness of no more than 145mm. Among them, the TH-07 is exclusively equipped with dual measurement apertures of 21mm and 7mm, which can not only meet the rapid detection of large-sized samples but also accurately measure the optical performance of small areas, making it suitable for more complex testing scenarios.   The entire series of equipment has a uniform volume of 310mm×215mm×540mm and weighs only 6kg. It is equipped with a USB interface and a stable DC 12V power supply, ensuring stable operation in both fixed laboratory testing and mobile spot checks on production lines.   III. Wide Application: Covering the entire industrial chain of optical materials The TH-07 series haze meter, with its powerful compatibility, has become the ideal choice for transparent material testing in multiple fields   In the display panel industry, the haze uniformity of the diffusion plate can be precisely measured to ensure the display effect of the screen. In the field of optical films, the light transmission performance of the films is optimized through transmittance detection. For AG glass in the automotive and electronic fields, it can efficiently evaluate the quality of anti-glare coatings. In the production of optical lenses, the optical clarity of the lenses can be strictly controlled, facilitating the quality upgrade of precision optical components. From basic materials to terminal products, the TH-07 series provides a "one-stop" testing solution for quality control throughout the entire industrial chain.   IV. Comprehensive Support: Customized solutions enhance testing efficiency To further meet the diverse testing requirements, dedicated fixtures suitable for films and cuvettes are provided. From custom-made diameter plates of 5mm, 7mm and 10mm to haze standard plates and transmittance plates calibrated by authoritative institutions such as the National Institute of Metrology and the East China Institute of Metrology, a complete ecosystem of "equipment + consumables + calibration services" has been formed. Users can flexibly select and configure according to the characteristics of the test object to enhance the detection efficiency and data credibility.   As an innovative product in the field of transparent material inspection, the TH-07 series touch screen haze meter, with its precise optical measurement, intelligent operation experience and comprehensive scene adaptation, brings more efficient and reliable quality control tools to the industry. CHNSpec Technology will continue to focus on optical inspection technology, promote the standardization of the industry through technological innovation, and help global manufacturing enterprises achieve quality upgrades and value enhancements.