This data set includes results for hormone and pharmaceutical compounds analyzed from 2012 through 2016 in laboratory quality-control samples that are associated with environmental samples collected by the National Water-Quality Assessment (NAWQA) Project during 2013 through 2015 for a study of groundwater resources used for drinking-water supply across the United States. Hormone and pharmaceutical results are provided for laboratory set blanks and reagent spikes analyzed during a time period that encompasses laboratory analysis of the environmental samples collected by NAWQA. This data release includes: Table 1. Hormone results for laboratory set blanks, December 18, 2012 through March 7, 2016. Table 2. Pharmaceutical results for laboratory set blanks, December 14, 2012 through March 4, 2016. Table 3. Hormone results for laboratory reagent spikes, June 17, 2013 through December 11, 2015. Table 4. Pharmaceutical results for laboratory reagent spikes, June 18, 2013 through October 1, 2015.

In-Vitro Diagnostics Quality Control Market is segmented by Products and Services (Quality Control Products, Data Management Solutions, and Quality Assurance Services), Applications (Immunochemistry, Hematology, Molecular Diagnostics, Coagulation/Hemostasis, and Other Applications), End Users (Hospitals, Clinical Laboratories, IVD Manufacturers & CROs and Other End Users), and Geography (North America, Europe, Asia-Pacific, Middle East and Africa, and South America). The market provides the value (in USD million) for the above-mentioned segments.

Quality is defined as the extent to which a product conforms to the design specifications and how it complies with the requirements of component functionality. For some industries, such as automotive and aeronautical, the quality of their parts is very important given the high requirements to which they are subject. However, difficulties arise from the fact that a measure of quality can only be evaluated ‘‘out-of-process”, resulting in losses because there is no alternative to removing defective parts from the production line. Therefore, it is necessary to apply Artificial Intelligence-based kits/solutions that provide in-process estimation to predict quality from some measured variables.

The main goal of these datasets is to monitor the final quality of the manufactured components or parts by estimating surface roughness from vibration signals and cutting parameters information using Artificial Intelligence-based solutions. Surface roughness is an essential feature in quality control defined by the deviation in the direction of the normal vector of a real surface from its ideal form. Because the roughness measurement is an offline and post process procedure, being able to estimate this value online brings a series of benefits in terms of time and cost reduction in manufacturing lines, energy efficiency, unnecessary wear of tools and machines, etc. Once a part has been detected with a surface quality below what is desired, a series of corrective measures can be applied for the following operations, such as: reducing the feed rate percentage, increasing the percentage of spindle speed or reducing the axial depth per pass, etc.

Global Air Quality Control System Market will grow at a CAGR of 6.2% during the forecast period, with an estimated size and share crossing USD 141.36 billion by 2032.

The Florida State University Center for Ocean-Atmospheric Predictions Studies (COAPS) has been operating a data assembly center (DAC) to collect, quality evaluate, and distribute Shipboard Automated Meteorological and Oceanographic System (SAMOS) observations since 2005. A SAMOS is typically a computerized data logging system that records underway meteorological and near-surface oceanographic observations collected on research vessels. The SAMOS initiative does not provide specific instrumentation for vessels, but instead takes advantage of science quality instrumentation already deployed on research vessels and select merchant ships. The SAMOS initiative provides vessel operators with desired sampling protocols and metadata requirements that will ensure the DAC receives a consistent series of observations from each vessel. The DAC and its partners in U. S. National Oceanic and Atmospheric Administration (NOAA), the University National Oceanographic Laboratory System, the U. S. Coast Guard, and the U. S. Antarctic Program have implemented a series of daily data transmissions from ship-to-shore using an email protocol. A set of observations recorded at one-minute intervals for the previous day arrive at the DAC soon after 0000 UTC and undergo automated quality evaluation. A trained data analyst reviews data and responds directly to vessels at sea when problems are identified. A secondary level of visual quality control is completed after all data from a single ship and day are merged into a common daily file (allowing for delayed data receipts). All quality-evaluated data are freely available to the user community and are distributed to national archive centers. This dataset contains all of these data.

The report covers Global Air Pollution Control Systems Companies and the market is segmented by Application (Power Generation, Cement Industry, Iron & Steel Industry, Chemical Industry, and Others), Type (Electrostatic Precipitators (ESP), Flue Gas Desulfurization(FGD), Scrubbers, Selective Catalytic Reduction (SCR), and Fabric Filters), and Geography (North America (United States, Canada, Rest of North America), Asia-Pacific (India, China, Japan, Australia, Rest of Asia-Pacific), Europe (Germany, France, United Kingdom, Italy, Rest of Europe), South America (Brazil, Argentina, Chile, Rest of South America), Middle-East and Africa (Saudi Arabia, South Africa, Algeria, Rest of Middle-East and Africa))

This statistic shows the resources dedicated for prevention and control of product quality by the Italian food company Barilla Group from 2013 to 2015. In 2015, the amount of resources dedicated to quality control processes was about 30 million euros.

Lemon dataset has been prepared to investigate the possibilities to tackle the issue of fruit quality control. It contains 2690 annotated images (1056 x 1056 pixels). Raw lemon images have been captured using the procedure described in the following blogpost and manually annotated using CVAT.

The market is segmented by Application (Power Generation, Cement Industry, Iron & Steel Industry, Chemical Industry, and Others), Type (Electrostatic Precipitators (ESP), Flue Gas Desulfurization(FGD), Scrubbers, Selective Catalytic Reduction (SCR), and Fabric Filters), and Geography (North America, South America, Asia-Pacific, Europe, and Middle-East and Africa)

These are timeseries plots of the first 1500 blobs in pdf format, made for quality control of primary data for the experiment ECHOG_A15_PRI_MM. After all checks of the data and metadata a persistent identifier was given to the experiment and the experiment was published. ( http://cera-www.dkrz.de/WDCC/ui/Compact.jsp?acronym=ECHOG_A15_PRI_MM) The plots have to be used as quick plots. Plots for scientific work or publications have to be made directly from the underlying data which are part of WDC-Climate and hence available for everyone who has been registered at the CERA data base.

The APAC Air Quality Control System Market is segmented by Application (Power Generation Industry, Cement Industry, Chemical Industry, Iron and Steel Industry, and Other Applications), Type (Electrostatic Precipitators (ESP), Flue Gas Desulfurization (FGD) and Scrubbers, Selective Catalytic Reduction (SCR), Fabric Filters, and Other Types), and Geography (India, China, Japan, Australia, and Rest of Asia-Pacific). The report offers market size and forecasts in revenue (USD billion) for all the above segments.

As per the recent market research conducted by FMI, the globalmolecular quality controls marketis expected to be valued at US$ 204 million in 2023. The market is expected to advance at 7.2% CAGR during the forecast period. By 2033, the estimation is anticipated to surge past US$ 408 million.

Country-wise Insights

Segmentation Insights

The Global Pharmaceutical Quality Control Market Size Was Worth USD 11 billion in 2023 and Is Expected To Reach USD 18 billion by 2032, CAGR of 12.2%.

The In Vitro Diagnostics Quality Control Market Share size & share value expected to touch USD 1.87 billion by 2032, to grow at a CAGR of 5.1% during the forecast period.

The North America industrial air quality control systems market is segmented by Type (Electrostatic Precipitators (ESP), Flue Gas Desulfurization(FGD), Scrubbers, Selective Catalytic Reduction (SCR), Fabric Filters, and Others), Application (Power Generation Industry, Cement Industry, Chemicals and Fertilizers, Iron and Steel Industry, Automotive Industry, Oil & Gas Industry, Other Applications), by Emissions (Qualitative Analysis only) (Nitrogen Oxides (NOx), Sulphur Oxides (SO2), Particulate Matter (PM)), and Geography (United States, Canada, Mexico). The report offers the market size and forecasts for North America industrial air quality control systems market (value in USD) for all the above segments.

Explore the detailed segmentation analysis of the Pharmaceutical Quality Control market. Understand detailed breakdown for each segment and uncover market opportunities.

This statistic shows the size of the data quality assurance industry in South Korea from 2010 to 2016 with an estimate for 2017. It was estimated that the data quality assurance market n South Korea would value around 112.7 billion South Korean won in 2017.

Question Paper Solutions of chapter Quality Control & Statistical Process Control of Operations Research, 2nd Semester , Master of Business Administration (2023-24)

Quality Assurance Services Market was valued at USD 5.3 Billion in 2024 and is projected to reach USD 12.9 Billion by 2031, growing at a CAGR of 11.2% during the forecast period 2024-2031.

Global Quality Assurance Services Market Drivers

The market drivers for the Quality Assurance Services Market can be influenced by various factors. These may include:

Increasing Complexity of Products and Services: The growing complexity of products and services across various industries necessitates robust quality assurance (QA) services to ensure compliance with standards and regulations.
Emphasis on Regulatory Compliance: Stringent regulatory requirements in industries such as healthcare, pharmaceuticals, aerospace, and automotive drive the demand for quality assurance services to meet regulatory standards and certifications.
Focus on Customer Experience: Organizations prioritize quality assurance to enhance customer satisfaction, improve product reliability, and maintain brand reputation through consistent delivery of high-quality products and services.
Globalization and Supply Chain Management: Globalization of supply chains requires rigorous quality control and assurance processes to manage product quality across international markets and ensure consistency.
Adoption of Industry 4.0 Technologies: Integration of advanced technologies such as IoT, AI, big data analytics, and automation in manufacturing and service sectors increases the need for quality assurance services to optimize processes and ensure product reliability.
Risk Management and Mitigation: Quality assurance services help mitigate risks associated with product defects, recalls, non-compliance, and potential legal liabilities, thereby protecting organizational assets and reputation.
Continuous Improvement Initiatives: Organizations adopt quality assurance as part of continuous improvement initiatives to achieve operational excellence, reduce waste, and enhance overall efficiency and productivity.
Demand for Software Testing Services: With the rise of digital transformation and software-driven solutions, there is an increasing demand for quality assurance services in software testing and validation to ensure application reliability and security.
Outsourcing Trends: Outsourcing of quality assurance services by organizations to specialized QA providers helps reduce costs, access expertise, and focus on core competencies, driving market growth.
Focus on Sustainable Practices: Increasing focus on sustainable practices and corporate social responsibility (CSR) encourages organizations to implement rigorous quality assurance measures to ensure environmental and ethical standards are met.

Automated Print Quality Inspection System Market size was valued at USD 1.5 Billion in 2023 and is projected to reach USD 3.8 Billion by 2030, growing at a CAGR of 12.5% during the forecast period 2024-2030.

Global Automated Print Quality Inspection System Market Drivers

The market drivers for the Automated Print Quality Inspection System Market can be influenced by various factors. These may include:

Quality Assurance and Cost Efficiency: In order to satisfy regulatory obligations as well as customer expectations, businesses are putting more and more emphasis on upholding high print standards. Real-time defect and error detection is made possible by automated print quality inspection systems, which also decrease the need for manual inspection and enhance overall quality control.
Growing Need in Printing Sector: To guarantee reliable and superior production, the printing sector—which includes labels, packaging, and commercial printing—is expanding, which is driving up demand for automated inspection systems.
Technological Developments: The creation of increasingly complex and precise automated print quality inspection systems is facilitated by ongoing developments in machine learning, artificial intelligence, and imaging technologies.
Increasing Production Speeds: There is a trend toward increasing production speeds as printing technology advance. In order to maintain quality control at these quicker production rates, automated inspection methods are essential.
Regulatory Compliance: In order to guarantee compliance and traceability, automated inspection systems are being adopted by a number of industries, including pharmaceuticals and food packaging, due to strict laws and requirements.
Cost Savings and Efficiency Gains: Automated systems not only produce faster and more consistent results than manual inspection, but they also help save labor expenses related to manual inspection, which improves overall operational efficiency.
Globalization of Supply Chains: Businesses must ensure uniform print quality throughout multiple sites as a result of the globalization of supply chains. Systems for automated inspection make it possible to implement worldwide standards for quality control.
Growing Industry 4.0 Adoption: Predictive maintenance is made easier by combining automated inspection systems with Industry 4.0 concepts like data analytics and the Internet of Things (IoT). This increases overall production efficiency.

Growing Awareness of Brand Protection: Manufacturers and brand owners are realizing how crucial it is to safeguard their reputations. Systems for automatically inspecting print quality are essential for making sure printed items adhere to brand guidelines.

Environmental Concerns: The emphasis on sustainable practices in manufacturing processes pushes the development of automated technologies that decrease waste by detecting and preventing faults early in the production cycle.