Complex Processing(복잡한 처리)란 무엇입니까?
Complex Processing 복잡한 처리 - However, complex processing, high cost, and low efficiency limit their widespread application. [1] Innovative processes of deep and complex processing of technogenic raw materials in the context of sustainable development of the mining industry and the economic challenges facing the mining industry should ensure the transition to a circular economy and the maximum use of natural resources. [2] The result of many years research of the university scientific community in the field of topical issues of complex processing of natural and man-made mineral raw materials was the creation of a scientific school “Dynamics of working bodies of machines and equipment for fine grinding of rocks” under the leadership of Professor Dmitrak Yu. [3] However, complex processing, low efficiency and severe oil fouling have always been the main obstacles to its application. [4] The study addresses the issue of complex processing of collagen-containing fish raw materials, and expansion of the range of specialized fish products of osteotropic action such as biocrips and protein bars. [5] Complex processing of industrial waste of individual industries, including wastewater treatment, containing sulfur anions and cations of heavy metals, in order to obtain both purified water and finished industrial products is an urgent task for today. [6] A complex processing was used including electroexplosion spraying of hafnium coating and subsequent electron-beam processing combined with nitriding. [7] One of the areas of rational use of raw materials, increasing the efficiency of medicinal plant raw materials and reducing the cost of medicines is the technology of its complex processing, which allows to obtain several pharmacologically active substances from one plant, also through the use of plant waste. [8] Since the most important for the contemporary tin industry are mineral raw materials, the possibility of complex processing of ore from the Syrymbet deposit was studied. [9] The work is devoted to solving the actual problem of the dairy industry - complex processing of food raw materials, expanding the range of dairy and milk-containing products of high nutritional value due to enrichment of protein, pro- and prebiotics, rational use of production resources by reducing the the technological process duration. [10] The radix 16 real-time complex fast Fourier transform (FFT) algorithm used in the digital spectrometer was obtained by improving and combining the parallel processing and complex processing of the FFT algorithm. [11] This determines the need to study the applicability of the fundamental cycle "structure-functional nature-properties" from the standpoint of physical chemistry of biopolymers both for the investigation of plant objects and for the development of modern technologies for complex processing based on the principles of "green chemistry". [12] The purpose of the work is to study the energy feasibility of using extrusion for dehydration of wet feed products during their complex processing in feed products. [13] While on the one hand, reading literature on a digital reading device might trigger a superficial processing of the text, and problems regarding orientation within the narrative, the awareness of reading a literary text might, on the other hand, lead to more in‐depth and complex processing, independent of reading medium. [14] The authors analyzed the phenolic profile, anti-radical potential, and the possibility of their complex processing for further use in functional foods. [15] The purpose of the conducted researches was studying of cones of a pine ordinary as source of polysaccharides in complex processing of raw materials. [16] The need for complex processing of waste from mining and processing industries in the North Caucasus is also dictated by environmental aspects due to the high risk of the occupied territories (they are located in floodplain terraced areas of mountain rivers) due to the flooding of mountain rivers, including the high vulnerability of resort and recreational and balneological complexes due to the negative impact of these negative sources. [17] The use of sour milk drinks with phytonutrients of different physical state will contribute not only to additional profits due to the sale of new biologically valuable and very important for public health products, but also to solve such an important problem of all food companies as complex processing of raw materials. [18] The new methodological approach is based on the complete exclusion of domestic waste landfill disposal in small towns in Russia and provides an effective scheme for waste collecting, advance preparation and container delivery for it complex processing with extensive use of the local railway transport network. [19] Taking into account the research results and morphostructural characteristics of cinders material, in particular, it is obvious that a number of technologies can be chosen for their complex processing; at the same time this determines further directions of their research, for example, the study of valuable impurity elements in them and their behavior in the process of changing the material of the dumps. [20] However, effective transplanted spinal cord scaffolds are restricted by poor mechanical integrity, topological cues, complex processing, or other properties. [21] In the process of automatic generation of interface test data, due to the numerous interface types, various formats, complex processing, and the lack of universal test data automatic generation method, the efficiency of interface test data generation is low and the coverage is insufficient. [22] The chemical composition of Palaemon adspersus shrimp characterizes it as a valuable source of high-protein and dietary products, which determines the feasibility of substantiating the directions of use in food technology and complex processing. [23] These materials can be used either in natural form (gravel, sand), or after a reduced processing (marble, large stone, for foundations), or after a complex processing (lime, plaster, cement, sandstone, clay). [24] The optimal algorithm for calculating the altitude and vertical flight speed of an aircraft, which is based on complex processing of information from static pressure sensors, outdoor air temperature, and vertical acceleration is described. [25] The existing synthetic approaches for high-performance WO3-based electrodes require energy-intensive instrumentation and complex processing, which hinder the development of flexible electrochromic (EC) energy storage devices. [26] Without further complex processing of the existing raw data, many crucial observations can be made from DTP which is otherwise very difficult to observe from Tafel plots. [27] Thus, the partial and complex processing in detecting tumors is restrained in the suggested model, adapting to the classification. [28] In order to solve the problem of unreadable data and complex processing in the process of aviation experiment. [29] This article focuses on the complex processing of quarry tuffs-stone to extract metals (iron, titanium, copper, silver, etc. [30] The rational technological scheme of complex processing of beef raw materials with production of protein, fat and mineral-protein additives was proposed. [31] In the course of research, the industrial types of iron ores of the deposit are studied, the distribution of rare metals by various industrial types, fractions of Lisakovsky iron ores and concentrates is considered The aim of the research is to study the characteristics of the ores of the Lisakovsky deposit for their complex processing. [32] According to the results of complex processing of space images by GoogleEarth, Landsat and field research, the regularities of the spread of dangerous exogenous processes and their connection with the local features of the river network and channel were revealed. [33] Theproblem of expanding the range of flour products of high nutritional and biological value for healthy nutrition with the use of new types of protein and mineral supplements, products of complex processing of fish and plant raw materials remains relevant. [34] For the Republic of Kazakhstan, like for any country with a developed mining and processing sector, it is important to develop knowledge to improve methods and technologies for the complex processing of raw materials, including those for the more complete extraction of precious metals. [35] Massive (raw) data transmission and complex processing are always involved in the existing methods, which results in undesired QoS such as real-time performance and privacy protection. [36]그러나 복잡한 처리, 높은 비용 및 낮은 효율성으로 인해 광범위한 적용이 제한됩니다. [1] 광산업의 지속 가능한 발전과 광산업이 직면한 경제적 도전의 맥락에서 기술 원료의 심층적이고 복잡한 처리의 혁신적인 프로세스는 순환 경제로의 전환과 천연 자원의 최대 사용을 보장해야 합니다. [2] 천연 및 인조 광물 원료의 복잡한 처리의 주제 분야에서 대학 과학 공동체의 다년간 연구의 결과는 과학 학교의 창설이었습니다. ” Dmitrak Yu 교수의 지도하에. [3] 그러나 복잡한 처리, 낮은 효율성 및 심각한 오일 오염은 항상 적용의 주요 장애물이었습니다. [4] 이 연구는 콜라겐 함유 어류 원료의 복잡한 가공 문제와 바이오크립 및 프로틴 바와 같은 골 형성 작용을 하는 특수 어류 제품의 범위 확장 문제를 해결합니다. [5] 정제수와 공산품 완제품을 모두 얻기 위해 황 음이온과 중금속 양이온을 포함하는 폐수 처리를 포함한 개별 산업의 산업 폐기물을 복합적으로 처리하는 것은 오늘날의 시급한 과제입니다. [6] 하프늄 코팅의 전기폭발 스프레이 및 질화와 결합된 후속 전자빔 처리를 포함하는 복잡한 처리가 사용되었습니다. [7] 원료의 합리적인 사용, 약용 식물 원료의 효율성 증가 및 의약품 비용 절감의 영역 중 하나는 복합 가공 기술로, 한 식물에서 여러 약리 활성 물질을 얻을 수 있습니다. 식물 폐기물. [8] 현대 주석 산업에서 가장 중요한 것은 광물 원료이기 때문에 Syrymbet 광상에서 광석의 복잡한 가공 가능성이 연구되었습니다. [9] 이 작업은 식품 원료의 복잡한 가공, 단백질, 프로바이오틱스 및 프리바이오틱스의 농축으로 인해 영양가가 높은 유제품 및 우유 함유 제품의 범위 확장, 생산의 합리적인 사용과 같은 낙농 산업의 실제 문제를 해결하는 데 전념하고 있습니다. 기술 프로세스 기간을 줄임으로써 자원을 절약할 수 있습니다. [10] 디지털 분광계에 사용되는 16기수 실시간 복소 고속 푸리에 변환(FFT) 알고리즘은 FFT 알고리즘의 병렬 처리와 복소 처리를 개선하고 결합하여 얻은 것입니다. [11] 이것은 식물 개체의 연구와 복합 가공을 위한 현대 기술의 개발 모두에 대한 생체 고분자의 물리 화학적 관점에서 기본 주기 "구조-기능적 성질-특성"의 적용 가능성을 연구할 필요성을 결정합니다. "녹색 화학". [12] 이 연구의 목적은 사료 제품의 복잡한 가공 과정에서 습식 사료 제품의 탈수를 위해 압출을 사용하는 에너지 타당성을 연구하는 것입니다. [13] 한편으로 디지털 판독 장치에서 문학을 읽는 것은 텍스트의 피상적인 처리를 촉발할 수 있고 내러티브 내의 방향에 관한 문제를 유발할 수 있지만 문학 텍스트를 읽는다는 인식은 다른 한편으로 더 깊이 있는 판독 매체와 무관한 복잡한 처리. [14] 저자는 페놀 프로파일, 항라디칼 가능성, 기능성 식품에 추가로 사용하기 위한 복합 가공 가능성을 분석했습니다. [15] 수행된 연구의 목적은 원료의 복합가공에서 다당류의 공급원으로서 보통의 소나무 콘을 연구하는 것이었다. [16] 북 코카서스의 광업 및 가공 산업에서 발생하는 폐기물의 복잡한 처리에 대한 필요성은 또한 산악 강의 범람으로 인한 점령 지역(산강의 범람원 계단식 지역에 위치)의 높은 위험으로 인해 환경적 측면에 의해 결정됩니다. , 이러한 부정적인 소스의 부정적인 영향으로 인한 리조트, 레크리에이션 및 온천 복합 단지의 높은 취약성을 포함합니다. [17] 물리적 상태가 다른 식물성 영양소를 함유한 신 우유 음료의 사용은 생물학적으로 가치가 있고 공중 보건에 매우 중요한 새로운 제품의 판매로 인한 추가 이익뿐만 아니라 복잡한 가공과 같은 모든 식품 회사의 중요한 문제를 해결하는 데 기여할 것입니다. 원료의. [18] 새로운 방법론적 접근 방식은 러시아의 작은 마을에서 가정 쓰레기 매립지 처리를 완전히 배제하는 것을 기반으로 하며 지역 철도 운송 네트워크를 광범위하게 사용하여 복잡한 처리를 위한 폐기물 수집, 사전 준비 및 컨테이너 운송을 위한 효과적인 계획을 제공합니다. [19] 특히 콘크리트 재료의 연구 결과와 형태 구조적 특성을 고려하면 복잡한 가공을 위해 여러 기술을 선택할 수 있음이 분명합니다. 동시에 이것은 연구의 추가 방향을 결정합니다. 예를 들어, 덤프의 재료를 변경하는 과정에서 중요한 불순물 요소와 행동에 대한 연구입니다. [20] 그러나 효과적인 이식된 척수 지지체는 열악한 기계적 무결성, 위상 단서, 복잡한 처리 또는 기타 특성으로 인해 제한됩니다. [21] 인터페이스 테스트 데이터의 자동 생성 과정에서 수많은 인터페이스 유형, 다양한 형식, 복잡한 처리 및 범용 테스트 데이터 자동 생성 방법의 부족으로 인해 인터페이스 테스트 데이터 생성의 효율성이 낮고 커버리지가 충분하지 않습니다. [22] Palaemon adspersus 새우의 화학 성분은 식품 기술 및 복잡한 가공에서 사용 방향을 입증하는 타당성을 결정하는 고단백 및 식이 제품의 귀중한 공급원으로 특징지어집니다. [23] 이러한 재료는 천연 형태(자갈, 모래) 또는 축소 처리(대리석, 큰 돌, 기초용) 또는 복잡한 처리(석회, 석고, 시멘트, 사암, 점토) 후에 사용할 수 있습니다. [24] 정압 센서, 외기 온도, 수직 가속도 정보를 복합적으로 처리하여 항공기의 고도와 수직 비행 속도를 계산하는 최적의 알고리즘을 설명합니다. [25] 고성능 WO3 기반 전극에 대한 기존의 합성 접근 방식은 에너지 집약적 기기와 복잡한 처리를 필요로 하므로 유연한 전기 변색(EC) 에너지 저장 장치의 개발을 방해합니다. [26] 기존 원시 데이터를 더 복잡하게 처리하지 않으면 Tafel 플롯에서 관찰하기 매우 어려운 DTP에서 많은 중요한 관찰을 수행할 수 있습니다. [27] 따라서 제안된 모델에서는 종양을 감지하는 부분적이고 복잡한 처리가 제한되어 분류에 적응합니다. [28] 항공 실험 과정에서 읽을 수 없는 데이터와 복잡한 처리 문제를 해결하기 위해. [29] 이 기사는 금속(철, 티타늄, 구리, 은 등)을 추출하기 위한 채석장 응회암의 복잡한 처리에 중점을 둡니다. [30] 단백질, 지방 및 미네랄 단백질 첨가제 생산과 함께 쇠고기 원료의 복합 가공에 대한 합리적인 기술 계획이 제안되었습니다. [31] 연구 과정에서 광상의 철광석의 산업 유형이 연구되고 다양한 산업 유형별 희소 금속의 분포, Lisakovsky 철광석의 분획 및 정광이 고려됩니다. 연구의 목적은 광석의 특성을 연구하는 것입니다 복잡한 처리를 위한 Lisakovsky 예금. [32] GoogleEarth, Landsat 및 현장 조사에 의한 공간 이미지의 복합 처리 결과에 따르면 위험한 외생 과정의 확산 규칙성과 하천 네트워크 및 수로의 국지적 특징과의 연관성이 밝혀졌습니다. [33] 새로운 유형의 단백질 및 미네랄 보충제, 생선 및 식물 원료의 복합 가공 제품을 사용하여 건강한 영양을 위해 영양 및 생물학적 가치가 높은 밀가루 제품의 범위를 확장하는 문제는 여전히 관련이 있습니다. [34] 카자흐스탄 공화국의 경우 광산 및 가공 부문이 발달한 다른 국가와 마찬가지로 귀금속의 보다 완전한 추출을 포함하여 원자재의 복잡한 가공을 위한 방법 및 기술을 개선하기 위한 지식을 개발하는 것이 중요합니다. [35] 기존 방식에는 항상 대규모(원시) 데이터 전송과 복잡한 처리가 수반되어 실시간 성능 및 개인 정보 보호와 같은 원치 않는 QoS가 발생합니다. [36]
laser micro nano 레이저 마이크로 나노
Significance The emerging technologies such as the Internet of Things and wearable technology in recent decades have brought great changes and convenience with better healthcare and manufacturing and higher safety, security, and efficiency for the whole society As an essential important link in these systems, sensors provide key value proposition and play a pivotal role Take wearable electronics as examples, the market value of wearable technology has doubled in the past five years Sensors have provided core functions for many different products during the development of wearable electronics, and they will continue to play a key role in future generation of products For example, smartwatches and skin patches are built based on the fitness tracking and daily activity data, and are used for medical measurement Virtual, augmented, and mixed reality devices rely on a set of sensors (e g inertial measurement unit, depth induction, force/pressure sensors) to enable users to interact with the content and environment Moreover, the transition from traditional human-computer interaction to a natural user interface will also depend on further advances in sensors Other products in different areas, such as autonomous vehicles, air detector, and smart clothing, are similar and depend on a set of core sensors that can interact with the body or the surrounding environment Some of these sensor systems have been gradually commercialized and expanded to more industrial, agricultural, military, environmental, and safety applications In particular, the COVID-19 pandemic in 2020 has also brought increased attention to sensors owing to their promising applications in tracking early onset and potential virus contacts, and remote patient monitoring of isolated patients In short, the sensor remains a fundamental component of the entire product line, which has been required to be thinner, lighter, smaller, more flexible, and sensitive in the new application systems Based on the important role of sensors, many preparation methods such as vapor deposition, lithography, nano-imprint lithography as well as printing have been developed Each technology has its unique advantages and adapts to different scenarios At the same time, their disadvantages that cannot be ignored also need to be addressed For instance, chemical and physical vapor deposition methods, including thermal evaporation, vacuum evaporation, magnetron sputtering, and molecular beam epitaxy, can produce high-quality materials and devices with good performance, but these technologies usually require expensive equipment and specific operating environment Moreover, it is difficult for these techniques to be compatible with flexible substrates and realize low-cost industrialized mass production In addition, photolithography and nano-imprint lithography are suitable for precision device fabrication However, they often face the challenges of low processing efficiency, low output, high cost due to the complex processing process, high design cost of mask, and long processing cycle In comparison, printing is a very attractive technology for low-cost large scale production But in most cases, the presence of mask limits the precision and resolution of the prepared micro/nano-sized devices Therefore, with the increasing demand for flexible, wearable, miniaturized, precise, integrated, and customized sensors, the new processing method with higher precision and more flexibility manners is needed to achieve controllable preparation To meet the developmental requirements of sensors, various processing techniques mentioned above are utilized to optimize and improve the sensor mainly from the aspects of the electrode, sensing material, and whole device In recent decade, laser micro-nano fabrication has been gradually developed and popular in the field of manufacturing The laser micro-nano fabrication changes the material state and property through the laser-material interaction and realizes the well-control of shape and property across scales With the advantages of large proc ssing speed, high precision, strong controllability, easy integration, and high compatibility with materials, the sensor fabricated by laser has ushered in a new development in structure regulation and performance optimization However, it still faces challenges and difficulties in mass production and efficiency promotion in practical applications Progress The laser processing technologies for the fabrication of sensors and sensing systems of different stimulus sources are summarized (Fig 2) Firstly, three laser processing modes widely used in sensor production including laser induced heating, reaction, and delamination are introduced The convenience and advantages of laser processing compared with those of the traditional processing technology can be clearly understood in the section of laser processing modes (Fig 3) Then, based on the existing research results, the sensor systems prepared by laser are classified into ultraviolet, gas, humidity, temperature, strain/stress, biology, and environmental monitoring sensors It is easily found that the advantages of laser micro-nano fabrication are mainly reflected in the following three aspects 1) Laser micro-nano fabrication has broadened the preparation approaches of electrodes and sensing materials It can realize in-situ or non-in-situ preparation of conductive electrodes and sensing materials by laser reduction, sintering, annealing, ablation, pulse deposition, laser induced carbonization, and hydrothermal reaction as well as other specific laser processing technologies, which provide alternative strategies for material preparation 2) Laser micro-nano fabrication simplifies the assembly process of the whole device The laser direct writing technology can realize in situ selective process in specific areas or specific materials, leading to great convenience for device construction Moreover, the whole sensor on flexible substrates can even be prepared by one-step laser fabrication through digital design 3) Laser micro-nano fabrication contributes to promote sensor performance Sensing material, as a key part of a single sensor, can be modified and regulated by laser processing, thus providing the possibility of performance optimization With these optimizations and improvements, the sensors become softer, smaller, and more customized and have higher integration Finally, we also analyze the problems existing in sensors fabricated by laser micro-nano fabrication, such as insufficient researches on laser-material interaction, limited processing accuracy and efficiency enhancement, and low level of device integration Conclusions and Prospect Laser micro-nano fabrication has gradually become a common and popular technology for sensing system preparation and integration To sum up, the sensor fabricated by laser still needs in-depth and detailed exploration to promote the development of commercialization and industrialization of the sensor © 2021, Chinese Lasers Press All right reserved. [1]Require Complex Processing 복잡한 처리 필요
However, the formation of desirable black-phase CsPbI3 requires complex processing at higher annealing temperatures and upon formation it suffers from instability issues at room temperature, hindering its potential for optoelectronic application. [1] Current in situ piezoresistive damage detection techniques for fiberglass-reinforced composites are limited in widespread application as they require complex processing techniques which inhibit the scalability of the methods. [2] Reaching out, grasping, and manipulating objects may seem like simple tasks, yet they require complex processing from a large network of brain regions. [3] However, SAR data has only recently become freely available with global coverage, and requires complex processing with specialized software to generate analysis-ready datasets. [4] Traditional covalent semiconductors require complex processing methods for device fabrication due to their high cohesive energies. [5] Current technologies to measure drug–target interactions require complex processing and invasive tissue biopsies, limiting their clinical utility for cancer treatment monitoring. [6] Commercially available biodegradable plastics, while minimizing their environmental impact and exhibiting a set of properties that enable the obtainment of industrial components, usually require complex processing methods, are costly and have limited applicability. [7]그러나 바람직한 흑색상 CsPbI3의 형성은 더 높은 어닐링 온도에서 복잡한 처리를 필요로 하며 형성 시 실온에서 불안정성 문제를 겪으며 광전자 응용에 대한 잠재력을 방해합니다. [1] 유리 섬유 강화 복합 재료에 대한 현재 현장 압저항 손상 감지 기술은 방법의 확장성을 억제하는 복잡한 처리 기술이 필요하기 때문에 광범위한 적용에서 제한적입니다. [2] nan [3] nan [4] 기존의 공유 반도체는 높은 응집 에너지로 인해 장치 제조를 위한 복잡한 처리 방법이 필요합니다. [5] nan [6] nan [7]
Involf Complex Processing 복잡한 처리 관련
Synthesis of hybrid nanomaterials in the lab-scale frequently involves complex processing and often is not able to be adopted in the industry without major enhancements for its commercial production. [1] However, this methodology is lengthy, involves complex processing leading to extraordinary losses, requires large amounts of starting materials, and is prone to artifacts due to the labile nature of mRNA. [2] Papermaking involves complex processing routes, and energy is required for collecting raw materials, producing chemicals, and pulp and papermaking. [3]실험실 규모의 하이브리드 나노물질 합성은 복잡한 공정을 수반하는 경우가 많으며 상업적 생산을 위한 주요 개선 사항 없이는 업계에서 채택할 수 없는 경우가 많습니다. [1] 그러나 이 방법론은 시간이 오래 걸리고 엄청난 손실을 초래하는 복잡한 처리를 포함하며 많은 양의 출발 물질이 필요하며 mRNA의 불안정한 특성으로 인해 인공물이 발생하기 쉽습니다. [2] nan [3]
Involve Complex Processing
Signal processing operations such as precoding, channel estimation, and decoding which involve complex processing can be simplified using Deep Learning (DL) algorithms in downlink Multiple-Input Multiple-Output Non-Orthogonal Multiple Access (MIMO-NOMA) system. [1] The existing approaches for directly prototyping a physical object involve complex processing steps, including CAD model reconstruction from the scanned point data, and/or stereolithography (STL) model generation. [2]복잡한 처리를 포함하는 프리코딩, 채널 추정 및 디코딩과 같은 신호 처리 작업은 다운링크 MIMO-NOMA(다중 입력 다중 출력 비직교 다중 액세스) 시스템에서 딥 러닝(DL) 알고리즘을 사용하여 단순화할 수 있습니다. [1] nan [2]
Les Complex Processing 덜 복잡한 처리
This paper expresses the performance of achievable sum rate linear precoding with variable signal-to-noise (SNR) ratio and achievable sum rate and several transmitter-receiver antennas, such as imperfect CSI, less complex processing and inter-user interference. [1] Handling large volumes of data and mining them for application-related services requires time-efficient and less complex processing. [2]이 논문은 불완전한 CSI, 덜 복잡한 처리 및 사용자간 간섭과 같은 가변 신호 대 잡음비(SNR) 및 달성 가능한 합 레이트 및 여러 송수신기 안테나를 사용하여 달성 가능한 합 레이트 선형 프리코딩의 성능을 표현합니다. [1] 대용량 데이터를 처리하고 애플리케이션 관련 서비스를 위해 마이닝하려면 시간 효율적이고 덜 복잡한 처리가 필요합니다. [2]
Eliminating Complex Processing 복잡한 처리 제거
The developed method can substantially improve hologram recording technology by eliminating complex processing procedures, which can lead to increasing the fabrication speed and reducing the cost. [1] The developed method can sabstantially improve hologram recording technology by increasing its speed, reducing the price, and eliminating complex processing procedures. [2]개발된 방법은 복잡한 처리 절차를 제거하여 홀로그램 기록 기술을 크게 향상시켜 제조 속도를 높이고 비용을 절감할 수 있습니다. [1] 개발된 방법은 속도를 높이고 가격을 낮추며 복잡한 처리 절차를 제거하여 홀로그램 기록 기술을 획기적으로 향상시킬 수 있습니다. [2]
complex processing procedure 복잡한 처리 절차
With more complex processing procedure, the risk of heavy metal contamination increases, especially with arsenic and cadmium. [1] The developed method can substantially improve hologram recording technology by eliminating complex processing procedures, which can lead to increasing the fabrication speed and reducing the cost. [2] However, it is still challenging to fabricate desirable electrospun substrates for organic solvent nanofiltration (OSN) owing to the relatively complex processing procedures and the organic operating environment. [3] The developed method can sabstantially improve hologram recording technology by increasing its speed, reducing the price, and eliminating complex processing procedures. [4] However, their successful application is commonly limited by low efficiency, vulnerability to acid/alkali, complex processing procedures, incapability for emulsion separation, etc. [5]보다 복잡한 처리 절차로 인해 특히 비소 및 카드뮴의 경우 중금속 오염의 위험이 증가합니다. [1] 개발된 방법은 복잡한 처리 절차를 제거하여 홀로그램 기록 기술을 크게 향상시켜 제조 속도를 높이고 비용을 절감할 수 있습니다. [2] nan [3] 개발된 방법은 속도를 높이고 가격을 낮추며 복잡한 처리 절차를 제거하여 홀로그램 기록 기술을 획기적으로 향상시킬 수 있습니다. [4] nan [5]
complex processing step
They are exposed to frequent stresses not only during complex processing steps, but also in the human body after intake. [1] The complex processing steps limit the industrial implementation of hydrometallurgy-dominant methods, which usually reclaim lithium in the last step, resulting in a poor recovery efficiency of lithium. [2] The existing approaches for directly prototyping a physical object involve complex processing steps, including CAD model reconstruction from the scanned point data, and/or stereolithography (STL) model generation. [3] The main unification improvements are: (1) consistent spatial tiling instead of various pixel clustering approaches, (2) uniform generation of sun and viewing angle dependent thresholds for individual tiles, (3) flexible study areas instead of area dependence, (4) parallel raster processing using the Open Computing Language (OpenCL), (5) and efficient algorithms for complex processing steps like histogram generation and analysis. [4]복잡한 가공 단계에서 뿐만 아니라 섭취 후 인체에도 빈번한 스트레스에 노출됩니다. [1] nan [2] nan [3] nan [4]
complex processing method 복잡한 처리 방법
Traditional covalent semiconductors require complex processing methods for device fabrication due to their high cohesive energies. [1] Aerogel has been widely known as a low-density and highly porous material and is closely connected with the complex processing methods, such as freeze-drying or supercritical drying. [2] Commercially available biodegradable plastics, while minimizing their environmental impact and exhibiting a set of properties that enable the obtainment of industrial components, usually require complex processing methods, are costly and have limited applicability. [3]기존의 공유 반도체는 높은 응집 에너지로 인해 장치 제조를 위한 복잡한 처리 방법이 필요합니다. [1] 에어로겔은 저밀도, 고다공성 물질로 널리 알려져 있으며 동결건조나 초임계건조 등 복잡한 가공방법과 밀접한 관련이 있다. [2] nan [3]
complex processing speed 복잡한 처리 속도
A two-factor complexity model that differentiated between simple and complex processing speed was the preferred model and fit the data well. [1] 1% of the variance) included primarily complex cognitive tests measuring executive function; verbal, visual, and working memory; and complex processing speed. [2] 018), complex processing speed (OR: 0. [3]단순 처리 속도와 복잡한 처리 속도를 구별하는 2요소 복잡도 모델이 선호되는 모델이며 데이터에 잘 맞습니다. [1] 분산의 1%)는 주로 실행 기능을 측정하는 복잡한 인지 테스트를 포함했습니다. 언어, 시각 및 작업 기억; 복잡한 처리 속도. [2] nan [3]
complex processing technique 복잡한 처리 기술
Current in situ piezoresistive damage detection techniques for fiberglass-reinforced composites are limited in widespread application as they require complex processing techniques which inhibit the scalability of the methods. [1] These insights challenge the conventional wisdom that pure HCP is difficult to access in linear block copolymer melts without the use of blending or other complex processing techniques. [2] Achieving this without using any high-cost reagent/additive and/or complex processing technique is another critical aspect for developing industrially viable alternatives to petroleum-based commodity plastics. [3]유리 섬유 강화 복합 재료에 대한 현재 현장 압저항 손상 감지 기술은 방법의 확장성을 억제하는 복잡한 처리 기술이 필요하기 때문에 광범위한 적용에서 제한적입니다. [1] 이러한 통찰력은 혼합 또는 기타 복잡한 가공 기술을 사용하지 않고 선형 블록 공중합체 용융물에서 순수한 HCP에 접근하기 어렵다는 기존의 통념에 도전합니다. [2] nan [3]
complex processing condition 복잡한 처리 조건
However, complex processing conditions and thermal stability, inherent of hybrid halide perovskite materials, remain urgent issues to be solved. [1] In this work, the aging behaviors of TBIR with ∼20 mol% butadiene units under thermo-oxidation, thermo-shearing and complex processing conditions were investigated in comparison with that of natural rubber (NR) and cis-1,4-polybutadiene (BR). [2] The optimization of multi-material parts relies on accurate forward prediction, which is challenging to achieve owing to the complex processing conditions in additive manufacturing and the resultant uncertainties in material properties. [3]그러나 하이브리드 할로겐화물 페로브스카이트 재료 고유의 복잡한 공정 조건과 열 안정성은 해결해야 할 시급한 문제로 남아 있습니다. [1] 이 연구에서 천연 고무(NR) 및 시스-1,4-폴리부타디엔(BR)과 비교하여 열산화, 열 전단 및 복잡한 가공 조건에서 ~20 mol% 부타디엔 단위를 사용하는 TBIR의 노화 거동을 조사했습니다. ). [2] nan [3]
complex processing system
Particularly, the battery management system (BMS) uses complex processing systems that perform measurements, estimation of the battery states, and protection of the system. [1] Generally this devices use a larger space, have multiple connections, external or integrate power supply and a complex processing systems. [2]특히, 배터리 관리 시스템(BMS)은 측정, 배터리 상태 추정 및 시스템 보호를 수행하는 복잡한 처리 시스템을 사용합니다. [1] nan [2]
complex processing chain 복잡한 처리 사슬
A complex processing chain is applied from the moment a raw image is acquired until the final image is obtained. [1] Images undergo a complex processing chain from the moment light reaches the camera’s sensor until the final digital image is delivered. [2]Raw 이미지가 획득되는 순간부터 최종 이미지가 획득될 때까지 복잡한 처리 체인이 적용됩니다. [1] 이미지는 빛이 카메라의 센서에 도달하는 순간부터 최종 디지털 이미지가 전달될 때까지 복잡한 처리 체인을 거칩니다. [2]
complex processing function 복잡한 처리 기능
This is particularly so for those cases where complex processing functions are required, such as those found in autonomous ATD/R systems. [1] Compared with traditional neural networks, deep learning networks have deeper and more network layers and can learn more complex processing functions. [2]자율 ATD/R 시스템에서 볼 수 있는 것과 같이 복잡한 처리 기능이 필요한 경우에 특히 그렇습니다. [1] 딥 러닝 네트워크는 기존 신경망에 비해 더 깊고 많은 네트워크 계층을 가지고 있으며 더 복잡한 처리 기능을 학습할 수 있습니다. [2]
complex processing proces 복잡한 처리 과정
Significance The emerging technologies such as the Internet of Things and wearable technology in recent decades have brought great changes and convenience with better healthcare and manufacturing and higher safety, security, and efficiency for the whole society As an essential important link in these systems, sensors provide key value proposition and play a pivotal role Take wearable electronics as examples, the market value of wearable technology has doubled in the past five years Sensors have provided core functions for many different products during the development of wearable electronics, and they will continue to play a key role in future generation of products For example, smartwatches and skin patches are built based on the fitness tracking and daily activity data, and are used for medical measurement Virtual, augmented, and mixed reality devices rely on a set of sensors (e g inertial measurement unit, depth induction, force/pressure sensors) to enable users to interact with the content and environment Moreover, the transition from traditional human-computer interaction to a natural user interface will also depend on further advances in sensors Other products in different areas, such as autonomous vehicles, air detector, and smart clothing, are similar and depend on a set of core sensors that can interact with the body or the surrounding environment Some of these sensor systems have been gradually commercialized and expanded to more industrial, agricultural, military, environmental, and safety applications In particular, the COVID-19 pandemic in 2020 has also brought increased attention to sensors owing to their promising applications in tracking early onset and potential virus contacts, and remote patient monitoring of isolated patients In short, the sensor remains a fundamental component of the entire product line, which has been required to be thinner, lighter, smaller, more flexible, and sensitive in the new application systems Based on the important role of sensors, many preparation methods such as vapor deposition, lithography, nano-imprint lithography as well as printing have been developed Each technology has its unique advantages and adapts to different scenarios At the same time, their disadvantages that cannot be ignored also need to be addressed For instance, chemical and physical vapor deposition methods, including thermal evaporation, vacuum evaporation, magnetron sputtering, and molecular beam epitaxy, can produce high-quality materials and devices with good performance, but these technologies usually require expensive equipment and specific operating environment Moreover, it is difficult for these techniques to be compatible with flexible substrates and realize low-cost industrialized mass production In addition, photolithography and nano-imprint lithography are suitable for precision device fabrication However, they often face the challenges of low processing efficiency, low output, high cost due to the complex processing process, high design cost of mask, and long processing cycle In comparison, printing is a very attractive technology for low-cost large scale production But in most cases, the presence of mask limits the precision and resolution of the prepared micro/nano-sized devices Therefore, with the increasing demand for flexible, wearable, miniaturized, precise, integrated, and customized sensors, the new processing method with higher precision and more flexibility manners is needed to achieve controllable preparation To meet the developmental requirements of sensors, various processing techniques mentioned above are utilized to optimize and improve the sensor mainly from the aspects of the electrode, sensing material, and whole device In recent decade, laser micro-nano fabrication has been gradually developed and popular in the field of manufacturing The laser micro-nano fabrication changes the material state and property through the laser-material interaction and realizes the well-control of shape and property across scales With the advantages of large proc ssing speed, high precision, strong controllability, easy integration, and high compatibility with materials, the sensor fabricated by laser has ushered in a new development in structure regulation and performance optimization However, it still faces challenges and difficulties in mass production and efficiency promotion in practical applications Progress The laser processing technologies for the fabrication of sensors and sensing systems of different stimulus sources are summarized (Fig 2) Firstly, three laser processing modes widely used in sensor production including laser induced heating, reaction, and delamination are introduced The convenience and advantages of laser processing compared with those of the traditional processing technology can be clearly understood in the section of laser processing modes (Fig 3) Then, based on the existing research results, the sensor systems prepared by laser are classified into ultraviolet, gas, humidity, temperature, strain/stress, biology, and environmental monitoring sensors It is easily found that the advantages of laser micro-nano fabrication are mainly reflected in the following three aspects 1) Laser micro-nano fabrication has broadened the preparation approaches of electrodes and sensing materials It can realize in-situ or non-in-situ preparation of conductive electrodes and sensing materials by laser reduction, sintering, annealing, ablation, pulse deposition, laser induced carbonization, and hydrothermal reaction as well as other specific laser processing technologies, which provide alternative strategies for material preparation 2) Laser micro-nano fabrication simplifies the assembly process of the whole device The laser direct writing technology can realize in situ selective process in specific areas or specific materials, leading to great convenience for device construction Moreover, the whole sensor on flexible substrates can even be prepared by one-step laser fabrication through digital design 3) Laser micro-nano fabrication contributes to promote sensor performance Sensing material, as a key part of a single sensor, can be modified and regulated by laser processing, thus providing the possibility of performance optimization With these optimizations and improvements, the sensors become softer, smaller, and more customized and have higher integration Finally, we also analyze the problems existing in sensors fabricated by laser micro-nano fabrication, such as insufficient researches on laser-material interaction, limited processing accuracy and efficiency enhancement, and low level of device integration Conclusions and Prospect Laser micro-nano fabrication has gradually become a common and popular technology for sensing system preparation and integration To sum up, the sensor fabricated by laser still needs in-depth and detailed exploration to promote the development of commercialization and industrialization of the sensor © 2021, Chinese Lasers Press All right reserved. [1] Because of the huge amount of information and complex processing process in imaging processing, we collect and calculate the key data on the basis of BP data model. [2]nan [1] 영상처리는 방대한 양의 정보와 복잡한 처리과정 때문에 BP 데이터 모델을 기반으로 주요 데이터를 수집하고 계산합니다. [2]