05321nam 2200613Ia 450 99621797780331620230421044516.01-281-75855-897866117585543-527-61513-X3-527-61512-1(CKB)1000000000375881(EBL)482324(OCoLC)814515363(SSID)ssj0000231061(PQKBManifestationID)11173755(PQKBTitleCode)TC0000231061(PQKBWorkID)10198527(PQKB)10885848(MiAaPQ)EBC482324(EXLCZ)99100000000037588119950818d1995 uy 0engur|n|---|||||txtccrQuality assurance in environmental monitoring[electronic resource] instrumental methods /edited by G. SubramanianWeinheim ;New York VCH19951 online resource (352 p.)Description based upon print version of record.3-527-28682-9 Includes bibliographical references and index.Quality Assurance in Environmental Monitoring; Contents; 1 The Use of Solid Phase Extraction for Environmental Samples; 1.1 The Importance of Sample Preparation; 1.2 Introduction to Solid Phase Extraction; 1.3 SPE Formats; 1.3.1 Syringe Barrel or Cartridges; 1.3.2 Syringe Filter or Sep-paks; 1.3.3 Disks; 1.3.4 Choice of Format; 1.4 Using SPE Cartridges and Disks; 1.5 SPE Sorbents; 1.5.1 Normal Phase Sorbents; 1.5.2 Reverse Phase Sorbents; 1.5.3 Ion Exchange Sorbents; 1.6 Sorbent and Solvent Relationships; 1.6.1 Normal Phase; 1.6.2 Reverse Phase; 1.6.3 Ion Exchange; 1.7 Selecting the Solvents1.7.1 Conditioning Solvents1.7.2 Loading Solvents; 1.7.3 Rinsing Solvents; 1.7.4 Elution Solvents; 1.8 Solvent Considerations; 1.8.1 Solvent Volume; 1.8.2 Solvent Miscibility; 1.8.3 Solvent Volatility; 1.8.4 Solvent Flow Rate; 1.9 Selecting Cartridge Size; 1.10 Method Development; 1.11 Matrix Considerations; 1.12 Analysis Considerations; 1.13 Method Considerations; 1.14 Example Methods; 2 Current Status of Supercritical Fluid Extraction in Environmental Analysis; 2.1 Introduction; 2.2 What is Supercritical Fluid; 2.3 Applicable Environmental Analytes and Matrices2.3.1 Polynuclear Aromatic Hydrocarbons and Polychlorinated Biphenyls2.3.2 Total Petroleum Hydrocarbons; 2.3.3 SFE of Wet Soils; 2.3.4 Pesticides; 2.3.5 Dibenzofurans/Dioxins; 2.4 Conclusions; 3 Validation and Quality Control with Atomic Absorption Spectrometry for Environmental Monitoring; 3.1 Introduction; 3.1.1 Use of Atomic Absorption Spectrometry in Environmental Monitoring; 3.1.2 The Need for Quality Control; 3.1.3 The Importance of Consistent Data; 3.1.4 Standardized/Reference Methods or Quality Control?; 3.1.5 The Degree of Analytical Quality Control; 3.1.6 Quality Control Principles3.2 Method Validation3.2.1 Basic Analytical Principles; 3.2.1 . 1 Preparation of Calibration/Standard Solutions; 3.2.1.2 Use of Characteristic Concentration/Mass; 3.2.2 Calibration; 3.2.2.1 The Importance of Calibration; 3.2.2.2 Influence of the Blank; 3.2.2.3 Type of Calibration Curve; 3.2.2.4 Linear or Non-Linear-Calibration; 3.2.2.5 Calibration by the Method of Analyte Additions; 3.2.2.6 Calibration Quality Coefficients; 3.2.3 Establishment of Performance Characteristics; 3.2.3.1 Assessment and Influence of Contamination; 3.2.3.2 Estimation of Detection Limits3.2.3.3 Recovery Measurements3.2.3.4 Precision; 3.2.3.5 Comparison with Alternative Techniqued/Methods; 3.2.3.6 Analysis of Certified Reference Materials; 3.3 Quality Control; 3.3.1 Frequency of Analysis and Choice of IQC Materials; 3.3.2 Preparation of In-house IQC Materials; 3.3.2.1 Establishment of IQC Target Values and Limits; 3.3.3 Use of Quality Control; 3.3.3.1 Defining a Quality Control Procedure; 3.3.4 Systematic and Random Errors; 3.4 External Quality Assessment; 3.5 Conclusions; 4 Application of ICP - OES Techniques in Environmental QC; 4.1 Introduction4.2 Theory of the ICP-OES TechniqueEnvironmental technology plays an increasingly important role in today's world. This has led to many new developments in legislation and monitoring of environmental pollutants.A comprehensive treatment of these current trends is presented in this book. The reader is helped by a sound understanding of modern instrumental methods such as GC/MS, thermal desorption and purge-trap methods, that are available to meet these legal requirements. Many practical applications assist familiarization with these techniques. This work pays particular attention to methods of monitoring different types PollutionMeasurementQuality controlPollutionMeasurementEquipment and suppliesPollutionMeasurementQuality control.PollutionMeasurementEquipment and supplies.363.7363628.50287Subramanian G.1935-863248MiAaPQMiAaPQMiAaPQBOOK996217977803316Quality assurance in environmental monitoring2230622UNISA01188nas 2200385- 450 991013619550332120241204164737.02229-6948(OCoLC)892856931(CKB)3720000000017517(CONSER)--2015257076(DE-599)ZDB2798315-8(EXLCZ)99372000000001751720141008auuuu9999 -u- -engurmnu||||||||txtrdacontentcrdamediacrrdacarrierICTACT journal on communication technologyChennai :ICT Academy of Tamil Nadu,[2010]-1 online resource0976-0091 IJCTJournal on communication technologyICTACT j. commun. technol.Communication and technologyPeriodicalsCommunication and technologyfast(OCoLC)fst00870044Periodicals.fastCommunication and technologyCommunication and technology.JOURNAL9910136195503321ICTACT journal on communication technology1947948UNINA05546nam 22007575 450 991064778320332120251009071946.09789811959325(electronic bk.)978981195931810.1007/978-981-19-5932-5(MiAaPQ)EBC7191408(Au-PeEL)EBL7191408(CKB)26089882600041(DE-He213)978-981-19-5932-5(PPN)268206554(EXLCZ)992608988260004120230204d2023 u| 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierDeployable Multimodal Machine Intelligence Applications in Biomedical Engineering /by Hongliang Ren1st ed. 2023.Singapore :Springer Nature Singapore :Imprint: Springer,2023.1 online resource (589 pages)Lecture Notes in Bioengineering,2195-2728Print version: Ren, Hongliang Deployable Multimodal Machine Intelligence Singapore : Springer,c2023 9789811959318 Includes bibliographical references.reviews orimimetic deployable mechanisms with potential functionalities in biomedical robotics -- Deployable and interchangeable telescoping tubes actuated with multiple tendons -- Deployable and foldable parallelogram mechanism for generating remote center of motion -- Origami Bending and Bistability for Transoral procedures -- Force-sensitive origami trihexaflexagon gripper actuated by foldable pneumatic bellows -- Untethered Inflatable Origami -- Wormigami and Tippysaurus origami structures -- Multi-leg insect-size soft foldable robots -- Magnetically Actuated Luminal Origami (MALO) -- Compressable and steerable Slinky motions -- Electromagnetically actuated origami structures for untethered optical steering -- Untethered soft ferromagnetic quad-jaws cootie catcher with selectively coupled degrees of freedom -- Wearable Origami Rendering Mechanism (WORM) for aspiring haptic illusions -- Wearable Compression-aware Force Rendering (CAFR) with deployable compression generating and sensing. These multi-DOF deployable robots integrated tactile interface sensing and multimodal actuation -- Kinesthesia sensorization of foldable tubular designs using soft sensors -- Flat Foldable Kirigami for Chipless Wireless Sensing -- Deployable kirigami for intra-abdominal monitoring -- Stretchable Strain Sensors by Kirigami Deployable on Balloons with Temporary Tattoo Paper -- Multi-DOF proprioceptive origami structures with fiducial markers and computer vision-based optical tracking -- Multimodal robotic deployable mechanisms with intelligent perception capabilities. .This book highlights the principles, design and characterization of mechanically compliant soft and foldable robots. Traditional rigid robots with bulky footprints and complicated components prolong the design iteration and optimization for keyhole and minimally invasive transluminal applications. Therefore, there is an interest in developing soft and foldable robots with remote actuation, multimodal sensing and machine intelligence. This book discusses the use of foldable and cuttable structures to design biomimetic deployable soft robots, that can exhibit a fair number of motions with consistency and repeatability. It presents the overall design principles, methodology, instrumentation, metamorphic sensing, multi-modal perception, and machine intelligence for creating untethered foldable active structures. These robotic structures can generate a variety of motions such as wave induction, compression, inchworm, peristalsis, flipping, tumbling, walking, swimming, flexion/extension etc.Remote actuation can control motions along regular and irregular surfaces from proximal sides. For self-deployable medical robots, motion diversity and shape reconfiguration are crucial factors. Deployable robots, with the use of malleable and resilient smart actuators, hold this crucial advantage over their conventional rigid robot counterparts. Such flexible structures capable of being compressed and expanded with intelligence perceptions hold enormous potential in biomedical applications.Lecture Notes in Bioengineering,2195-2728Biomedical engineeringMedical physicsRoboticsNanoelectromechanical systemsComputational intelligenceAutomatic controlAutomationBiomedical Engineering and BioengineeringMedical PhysicsRoboticsNanoscale DevicesComputational IntelligenceControl, Robotics, AutomationBiomedical engineering.Medical physics.Robotics.Nanoelectromechanical systems.Computational intelligence.Automatic control.Automation.Biomedical Engineering and Bioengineering.Medical Physics.Robotics.Nanoscale Devices.Computational Intelligence.Control, Robotics, Automation.610.285Ren Hongliang1280718MiAaPQMiAaPQMiAaPQ9910647783203321Deployable Multimodal Machine Intelligence3017416UNINA