03886nam 22004453 450 991016321370332120230803215327.097817828967221782896724(CKB)3810000000097970(MiAaPQ)EBC5626002(Au-PeEL)EBL5626002(CaPaEBR)ebr11642250(OCoLC)1080999207(Perlego)3021568(EXLCZ)99381000000009797020210901d2014 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierAirborne Deep Operational Maneuver1st ed.Chicago :Tannenberg Publishing,2014.©2014.1 online resource (46 pages)Intro -- TABLE OF CONTENTS -- ABSTRACT -- SECTION I: INTRODUCTION -- SECTION II: DEFINITION OF TERMS -- SECTION III: NORMANDY AS A CASE-STUDY FOR THE USE OF AIRBORNE FORCES TO CONDUCT OPERATIONAL MANEUVER -- SECTION IV -- CURRENT FEASIBILITY OF THE USE OF AIRBORNE FORCES TO CONDUCT OPERATIONAL MANEUVER -- SECTION V: THE THEORY OF AIRBORNE OPERATIONAL MANEUVER -- SECTION VI: A SYNTHESIS OF MODERN EMPLOYMENT OPTIONS FOR AIRBORNE FORCES IN THE CONDUCT OF OPERATIONAL MANEUVER -- SECTION VII: IMPLICATIONS FOR THE FUTURE USES OF AIRBORNE FORCES FOR OPERATIONAL MANEUVER -- BIBLIOGRAPHY -- Books -- Periodicals. Papers, and Speeches -- Military/Government Publications.The purpose of this paper is to answer two questions. The first question is: Is it feasible to use airborne forces to penetrate enemy airspace and to conduct a vertical envelopment to effect deep operational maneuver? If it is feasible, what are the employment options available for the use of such an airborne force in the conduct of a modern military campaign? To examine these questions, the paper begins with some definitions to provide a common frame of reference. The use of airborne forces in World War II is next examined to determine if the use of airborne forces to effect deep operational maneuver is historically feasible. Next, the contemporary threat is discussed as it is relevant to the employment of airborne forces in a modern context. Next, the feasibility of the use of airborne forces with some limitations to conduct deep operational maneuver is established in the context of the maneuver, firepower, and protection aspects of the combat power model. Next, the theory of deep operations and the use of airborne forces to conduct these kinds of deep maneuvers is examined in the theories of Clausewitz, Jomini, Tukhachevskiy, Triandafillov, and Simpkin. Next, six employment options for the use of airborne forces to conduct deep operations in a modern context are deduced. They are: (1) an airborne force can be used to create a second front within a theater of operations; (2) an airborne force can be used to operationally contain an enemy force targeted for destruction within a theater of operations; (3) an airborne force can be used to seize a "bridgehead"...; (4) an airborne force can conduct coups de main against high value targets within a theater of operations; (5) an airborne force can conduct light operations in a theater of operations to disrupt and disorganize the enemy's rear facilities and networks and have a cumulative operational impact; and (6) an airborne force can conduct expeditionary operations to achieve political, strategic, and operational aims Airborne operations (Military science)Airborne operations (Military science)356.16609729999999Davis Major Danny M1376660MiAaPQMiAaPQMiAaPQBOOK9910163213703321Airborne Deep Operational Maneuver3412627UNINA06338nam 2201393z- 450 991055753030332120210501(CKB)5400000000044275(oapen)https://directory.doabooks.org/handle/20.500.12854/69030(oapen)doab69030(EXLCZ)99540000000004427520202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierAdvanced Intelligent Control through Versatile Intelligent Portable PlatformsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (322 p.)3-03936-996-2 3-03936-997-0 Advanced intelligent (ADI) control through Versatile Intelligent Portable (VIP) Platforms is a rapidly developing, complex, challenging field with great practical importance and potential. ADI control is an interdisciplinary field which combines and extends theories and methods from control theory, computer science, and operations research areas with the aim of developing controllers that are highly adaptable to significant unanticipated changes. Deep research and communicating new trends in the design, control, and applications of the real time control of intelligent sensors systems using advanced intelligent control methods and techniques is the main purpose of this book. Innovative multi-sensor fusion techniques, integrated through VIP platforms, are developed and combined with computer vision, virtual and augmented reality (VR&AR), and intelligent communication, including remote control, adaptive sensor networks, human-robot (H2R) interaction systems, and machine-to-machine (M2M) interfaces. Intelligent decision support systems (IDSS), including remote sensing, and their integration with DSS, GA-based DSS, fuzzy sets DSS, rough set-based DSS, intelligent agent-assisted DSS, process mining integration into decision support, adaptive DSS, computer vision-based DSS, and sensory and robotic DSS are highlighted in the field of advanced intelligent control. Approaching new technologies using advanced intelligent control through versatile intelligent portable platforms involves complex multidisciplinary research covering enhanced IoT technologies and applications in the 5G densification era, bio-inspired techniques in future manufacturing enterprise control, cyberphysical systems approach to cognitive enterprise, developing the IT Industry 4.0 concept, industrial systems in the digital age, cloud computing, robotics, and automation with applications such as human aid mechatronics moving in unstructured and uneven environments, rescue robots, firefighting robots, rehabilitation robots, robot-assisted surgery, and domestic robots.History of engineering and technologybicssc3D scanning3D shape reconstructionaccessibilityadaptive automation and controlleradaptive kalmanadaptive sensor networksadvanced driver-assistance system (ADAS)advanced intelligent controlair monitoringAndroidautism spectrum disorderautomatic distortion rectificationback-endcarboncomputer visionconnected bikecontrolconvolutional neural networkscritical infrastructurescyber-physical systemsdeep learningdroneelectrical conductivityembeddedengagement indexEOG artifactexoskeleton handface recognitionfacial emotion recognitionfiducial markersfish-eye lensfractional order modelfront-endgame-based learninghuman-robot interactionhybrid neural networksimperfect dataindependent component analysisintelligent controlintelligent cyber enterpriseintelligent decision support systemsintelligent remote control and communicationIoTkernellower limbmachine-learning classifiermeasurement fusionmicro-wiremicroinjection sensormodulesmonitoringmotion intention acquisitionMPWM microfluidic transportMQTTmulti-sensor systemnanowiresNAO robotnew technologiesoptical measurementsoxidationPassive Brain SignalsPDMS capillarypersonalized trainingphotodetectorpicolitre volume measurementpollutantpositioning systemquadcopterquantum particle swarm optimizationrehabilitation robotRGB-D sensorsrobot control intelligent sensor systemssilver catalystsmart technologiessmartphone securitysoftware sensor datastatic torque sensorsupport vector machinessystematic literature reviewsystems interfacetraining taskuser experienceversatile intelligent portable platformsvideo-surveillancevirtual and augmented realityvision taskswide-angle lensβ-Ga2O3History of engineering and technologyVladareanu Luigeedt1327790Vladareanu LuigeothBOOK9910557530303321Advanced Intelligent Control through Versatile Intelligent Portable Platforms3038102UNINA