Technology and Agribusiness : : How the Technology Is Impacting the Agribusiness.

Technology and Agribusiness : : How the Technology Is Impacting the Agribusiness.

This book discusses the major problems in agribusiness and technologies that can be applied to solve and improve such issues. Agribusiness covers topics such as arable farming, dairy farming, fruits, vegetables, meat, etc. Each domain has different needs that can be addressed through smart agricultu...

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Grimblatt, Victor.
Place / Publishing House:Aalborg : : River Publishers,, 2021.
©2021.
Year of Publication:2021
Edition:1st ed.
Language:English
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Physical Description:1 online resource (351 pages)
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spelling Grimblatt, Victor.
Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
1st ed.
Aalborg : River Publishers, 2021.
©2021.
1 online resource (351 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Intro -- Series Editors -- Amara Amara -- IEEE CASS President -- Yen-Kuang Chen -- VP - Technical Activities, IEEE CASS -- Yoshifumi Nishio -- VP - Regional Activities and Membership, -- Table of contents -- Introduction -- CHAPTER 01 -- IoT in the Agribusiness:Technology Tren -- Alfredo Arnaud -- Matías Miguez -- Universidad Católica del Uruguay, Montev -- RFID: Radio Frequency ID -- RFID Technologies and Classification -- RFID Tag Types (II) -- Main (at the present) passive RFID frequ -- RFID Mainstream -- RFID Applications in the Agribusiness -- RFID Tags for Animal ID -- Localization &amp -- Geolocalization -- Connectivity -- Uruguay -- Traceability Within The Fish Industry -- RFID in The Wood Industry -- RFID Based Sensors (I) -- RFID Based Sensors (II) -- Application Example: Semi-active LF Temp -- Objective - To Increase Reading Distance -- Proposed Topology - Not Only For Sensors -- Proposed Topology -- ASIC Prototype and Measurements -- IoT: Internet of Things -- IoT in the Agribusiness -- IoT Primary Market Is Still The Smart Ci -- An IoT Technology Classification (I) -- An IoT Technology Classification (II) -- An IoT Technology Classification (III) -- Single or Few Nodes… Using the TelCo -- Multi-node Network Example -- Geolocalization of Cattle… Using Farm Ar -- IoT Example: Nursery Plants Monitoring -- 3GPP Technologies -- IoT Under 3GPP For The Agribusiness Appl -- IoT Under 3GPP For The Agribusiness Appl -- Trend: Satellite IoT… Game-changer -- LoRa Based Direct Satellite Access -- ISO 11784/11785 Compliant RFID Reader -- The Reader (I) -- The Reader (II) -- Current Trend: RFID Reader -&gt -- Beyond Tra -- Current Trend: Bring the Data-Base to Th -- Bring The Data-base to The Cattleyards ( -- Bring The Data-base to The Cattleyards ( -- FAN: Farm Area Network -- Battery Powered Remote Telemetry Unit (R.
Battery Powered RTU for Ilegal Logging D -- RTU Power Consumption Profile Along Time -- Energy Consumption Measurements -- Optimal Datagram Size -- Energy Consumption Measurements Overview -- Additional HW &amp -- Communication Strategy ( -- Additional HW &amp -- Communication Strategy ( -- Partial Conclusions (I) -- Partial Conclusions (II) -- DIEstro A 5µA IoT PLATFORM FOR CATTLE HE -- AN IoT-BASED ELECTRONIC PRICE-TAG FOR FO -- SMARTNOZZLE -- CONCLUSIONS -- CHAPTER 02 -- Fruit Sector in Chile -- Álvaro Reyes -- Universidad Santo Tomás, Santiago, Chile -- Outline -- Introduction (I) -- Introduction (II) -- Introduction (III) -- Cultivated Area by Type of Farmers (Hect -- Foreign Trade Fruit Sector (I) -- Foreign Trade Fruit Sector (II) -- 1. FRUIT PRODUCTION IN CHILE -- Planted Area With Fruit Crops (Hectares) -- Chilean Fruit Exports 2008-2018 -- 2. STRENGTHS -- Strengths (I) -- Strengths (II) -- Strengths (III) -- 3. CHALLENGES -- Challenges (I) -- Challenges (II) -- Challenges (III) -- Final Remarks -- References -- CHAPTER 03 -- Internet of Things for Data Driven Preci -- Yosi Shacham Diamand -- Tel Aviv University, Tel Aviv, Israel -- 1. THE NEED FOR SENSING IN AGRICULTURE -- Need for Sensing in Agriculture (I) -- Need for Sensing in Agriculture (II) -- Need for Sensing in Agriculture (III) -- Need for Sensing in Agriculture (IV) -- Need for Sensing in Agriculture (V) -- Need for Sensing in Agriculture (VI) -- 2. AVENUES FOR SMART AND PRECISION AGRIC -- Avenues for Smart and Precision Agricult -- Avenues for Smart and Precision Agricult -- 3. SENSING IN AGRICULTURE -- Sensing in agriculture: indirect sensing -- Sensing in agriculture: direct sensing -- Sensing in Agriculture: Functional Sensi -- 4. THE DIGITAL VILLAGE -- The Idea is to Generate Data -- Site maps -- Not far from the Himalaya -- Rishikesh in the Himalayan foothills bes.
The Ganges river at the Himalaya… -- 5. OUR APPROACH -- The Digital Village. -- Goals -- Motivation -- Objectives -- Deliverable -- Novelty and Interdisciplinary Nature of -- Approach -- Possible Solutions -- Our Approach (I) -- Our Approach (II) -- 6. METHODOLOGY -- Methodology (I) -- Methodology (II) -- Methodology: Data acquisition (I) -- Methodology: Data acquisition (II) -- Methodology: Data acquisition (III) -- Methodology: pre-deployment -- Methodology: Data storage -- Methodology: Data Analysis -- Methodology -- 7. FEASIBILITY -- Pilot project -- Feasibility -- Feasibility Studies -- AT The Rice Field in Punjab (I) -- AT The Rice Field in Punjab (II) -- AT The Rice Field in Punjab (III) -- Feasibility Studies (I) -- Feasibility Studies (II) -- Feasibility Studies: Data Retrieval Plat -- Feasibility Studies: Data Retrieval Plat -- The Main Problem With Existing IoT Syste -- Internet of Things (IoT) Networks: Proto -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Rice Fields in Punjab -- Rice Harvesting -- Rice Collection -- Rice Primary Storage -- Future Plans -- Conclusions -- Map -- CHAPTER 04 -- Improved IoT Capabilities for Agricultur -- François Rivet -- Université de Bordeaux, France -- Guillaume Ferré -- Université de Bordeaux, France -- DCSS for IoT Everywhere Using -- Guillaume Ferré -- Université de Bordeaux, France -- 1. INTRODUCTION -- IoT Radio and Network links -- IoT general system -- LPWAN -- Introduction - 25% -- LEO Satellites (I) -- LEO Satellites (II) -- LEO Satellites (III) -- LEO Satellites Main Issues -- Digital Communication Techniques -- Motivations -- Contributions -- LoRa Tx/Rx Principle (Transmitter) -- LoRa Tx/Rx Principle (Receiver).
System Model (Transmitted Signal) (I) -- System Model (Transmitted Signal) (II) -- LoRa -- Frequency Error Tolerance -- LoRa Packet Structure -- CSS when Desynchronizations Occur (I) -- CSS when Desynchronizations Occur (II) -- CSS when Desynchronizations Occur (III) -- An Introduction (I) -- An Introduction (II) -- Performance (I) -- Performance (II) -- Performance (III) -- CFO Robustness (I) -- CFO Robustness (II) -- DCSS - DR Robustness (I) -- DCSS - DR Robustness (II) -- DCSS - DR Robustness (III) -- DCSS - DR Robustness (IV) -- FoV: SIC / FDMA (I) -- FoV: SIC / FDMA (I) -- Proposed Algorithm -- Strongest Signal Synchronization Algorit -- Simulation of Synthesized Signals -- Experimental Validation (I) -- Experimental Validation (II) -- Experimental Validation (III) -- Experimental Validation (IV) -- In Downlink (I) -- In Downlink (II) -- Conclusion -- 2. CSS -- 3. CSS WHEN DESYNCHRONIZATIONS OCCUR -- 4. DCSS -- 5. DR ROBUSTNESS -- 6. FoV: SIC / FDMA -- 6. CONCLUSION -- Internet of Things Device Power -- François Rivet -- Université de Bordeaux, France -- Billions of Things … -- But hardware is the key … -- It is more than data -- IoT in the countryside -- Data -- Idea -- IoT Device Operating -- Edge vs Cloud Computing -- Environmental Signals -- Regression Model (I) -- Regression Model (II) -- Regression -- Regression Model (III) -- Regression Model (IV) -- Regression Model (V) -- Regression Model (VI) -- % Error over a day -- The Order Depends on ... -- Experiment -- Digital implementation -- The Data Frame -- Coding of Coefficients -- 3-week Experiment -- 3-week Experiment Results -- 3-week Experiment Feedback -- Consumption Measurements -- Conclusion -- CHAPTER 05 -- Low Power Soc Design Flow and Methodolog -- Ronald Valenzuela -- Synopsys, Santiago, Chile -- Outline -- Applications -- Integration (I) -- The Beginning -- Integration (II).
Gordon E. Moore's Law (I) -- Gordon E. Moore's Law (II) -- About Circuits -- At the Foundry: Circuits are Printed in -- At the Foundry: Circuits are Printed in -- The Concept -- Basic Steps of Digital Design Flow (I) -- Basic Steps of Digital Design Flow (II) -- Digital IC Specification -- Logic Simulations -- Logic Synthesis (I) -- Logic Synthesis (II) -- Logic Synthesis (III) -- Logic Synthesis optimizations -- Formal Verification -- Digital Design Flow -- Physical Synthesis Steps -- Design Planning: Floorplan -- Design Planning: Power Network Synthesis -- Placement -- Clock Distribution -- Clock Tree Synthesis -- Routing -- Some Remarks Regarding Integration (I) -- Some Remarks Regarding Integration (II) -- Mainstream Optimizations -- Clock-Gating Insertion -- Self-Gating -- Architectural Optimization (I) -- Architectural Optimization (II) -- Integrated Multibit Banking and Debankin -- Power Sizing &amp -- Multi-threshold Optimizat -- Low Power Placement -- Glitch Reduction -- Dependency on Simulation Vectors -- Advanced Low Power Design Techniques -- Power Gating (Shutdown) -- Multi-Voltage -- Multi-Voltage with Shutdown -- Dynamic Voltage (and Frequency) Scaling -- Verification Challenge: Power Management -- Summary of Low Power Impact on Design Fl -- RTL Designers Need Power Intent -- UPF - A Brief History -- Defining Power Domains -- Defining Your Power Intent -- Functional Intent vs. Power Intent -- INTRODUCTION -- DESIGN FLOW -- CLOC DESIGN FLOW: PHYSICAL SYNTHESIS -- AUTOMATIC LOW POWER TECHNIQUES -- MULTI VOLTAGE WITH IEEE1801 -- CHAPTER 06 -- g/I Technique for Analog Circuit Design -- Angel Abusleme -- Pablo Walker -- Pontificia Universidad Católica de Chile -- Agribusiness Sensors and IoT -- Analog Front-ends -- Talk Outline -- ELECTRONIC AMPLIFIER DESIGN -- Analog IC Design Flow -- The Amplifier.
The Amplifier on a Feedback Configuratio.
This book discusses the major problems in agribusiness and technologies that can be applied to solve and improve such issues. Agribusiness covers topics such as arable farming, dairy farming, fruits, vegetables, meat, etc. Each domain has different needs that can be addressed through smart agriculture technologies such as circuits and systems.
Description based on publisher supplied metadata and other sources.
Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
Internet of things.
Agricultural industries--Technological innovations.
Electronic books.
Print version: Grimblatt, Victor Technology and Agribusiness: How the Technology Is Impacting the Agribusiness Aalborg : River Publishers,c2021
ProQuest (Firm)
https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=30169264 Click to View
language English
format eBook
author Grimblatt, Victor.
spellingShingle Grimblatt, Victor.
Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
Intro -- Series Editors -- Amara Amara -- IEEE CASS President -- Yen-Kuang Chen -- VP - Technical Activities, IEEE CASS -- Yoshifumi Nishio -- VP - Regional Activities and Membership, -- Table of contents -- Introduction -- CHAPTER 01 -- IoT in the Agribusiness:Technology Tren -- Alfredo Arnaud -- Matías Miguez -- Universidad Católica del Uruguay, Montev -- RFID: Radio Frequency ID -- RFID Technologies and Classification -- RFID Tag Types (II) -- Main (at the present) passive RFID frequ -- RFID Mainstream -- RFID Applications in the Agribusiness -- RFID Tags for Animal ID -- Localization &amp -- Geolocalization -- Connectivity -- Uruguay -- Traceability Within The Fish Industry -- RFID in The Wood Industry -- RFID Based Sensors (I) -- RFID Based Sensors (II) -- Application Example: Semi-active LF Temp -- Objective - To Increase Reading Distance -- Proposed Topology - Not Only For Sensors -- Proposed Topology -- ASIC Prototype and Measurements -- IoT: Internet of Things -- IoT in the Agribusiness -- IoT Primary Market Is Still The Smart Ci -- An IoT Technology Classification (I) -- An IoT Technology Classification (II) -- An IoT Technology Classification (III) -- Single or Few Nodes… Using the TelCo -- Multi-node Network Example -- Geolocalization of Cattle… Using Farm Ar -- IoT Example: Nursery Plants Monitoring -- 3GPP Technologies -- IoT Under 3GPP For The Agribusiness Appl -- IoT Under 3GPP For The Agribusiness Appl -- Trend: Satellite IoT… Game-changer -- LoRa Based Direct Satellite Access -- ISO 11784/11785 Compliant RFID Reader -- The Reader (I) -- The Reader (II) -- Current Trend: RFID Reader -&gt -- Beyond Tra -- Current Trend: Bring the Data-Base to Th -- Bring The Data-base to The Cattleyards ( -- Bring The Data-base to The Cattleyards ( -- FAN: Farm Area Network -- Battery Powered Remote Telemetry Unit (R.
Battery Powered RTU for Ilegal Logging D -- RTU Power Consumption Profile Along Time -- Energy Consumption Measurements -- Optimal Datagram Size -- Energy Consumption Measurements Overview -- Additional HW &amp -- Communication Strategy ( -- Additional HW &amp -- Communication Strategy ( -- Partial Conclusions (I) -- Partial Conclusions (II) -- DIEstro A 5µA IoT PLATFORM FOR CATTLE HE -- AN IoT-BASED ELECTRONIC PRICE-TAG FOR FO -- SMARTNOZZLE -- CONCLUSIONS -- CHAPTER 02 -- Fruit Sector in Chile -- Álvaro Reyes -- Universidad Santo Tomás, Santiago, Chile -- Outline -- Introduction (I) -- Introduction (II) -- Introduction (III) -- Cultivated Area by Type of Farmers (Hect -- Foreign Trade Fruit Sector (I) -- Foreign Trade Fruit Sector (II) -- 1. FRUIT PRODUCTION IN CHILE -- Planted Area With Fruit Crops (Hectares) -- Chilean Fruit Exports 2008-2018 -- 2. STRENGTHS -- Strengths (I) -- Strengths (II) -- Strengths (III) -- 3. CHALLENGES -- Challenges (I) -- Challenges (II) -- Challenges (III) -- Final Remarks -- References -- CHAPTER 03 -- Internet of Things for Data Driven Preci -- Yosi Shacham Diamand -- Tel Aviv University, Tel Aviv, Israel -- 1. THE NEED FOR SENSING IN AGRICULTURE -- Need for Sensing in Agriculture (I) -- Need for Sensing in Agriculture (II) -- Need for Sensing in Agriculture (III) -- Need for Sensing in Agriculture (IV) -- Need for Sensing in Agriculture (V) -- Need for Sensing in Agriculture (VI) -- 2. AVENUES FOR SMART AND PRECISION AGRIC -- Avenues for Smart and Precision Agricult -- Avenues for Smart and Precision Agricult -- 3. SENSING IN AGRICULTURE -- Sensing in agriculture: indirect sensing -- Sensing in agriculture: direct sensing -- Sensing in Agriculture: Functional Sensi -- 4. THE DIGITAL VILLAGE -- The Idea is to Generate Data -- Site maps -- Not far from the Himalaya -- Rishikesh in the Himalayan foothills bes.
The Ganges river at the Himalaya… -- 5. OUR APPROACH -- The Digital Village. -- Goals -- Motivation -- Objectives -- Deliverable -- Novelty and Interdisciplinary Nature of -- Approach -- Possible Solutions -- Our Approach (I) -- Our Approach (II) -- 6. METHODOLOGY -- Methodology (I) -- Methodology (II) -- Methodology: Data acquisition (I) -- Methodology: Data acquisition (II) -- Methodology: Data acquisition (III) -- Methodology: pre-deployment -- Methodology: Data storage -- Methodology: Data Analysis -- Methodology -- 7. FEASIBILITY -- Pilot project -- Feasibility -- Feasibility Studies -- AT The Rice Field in Punjab (I) -- AT The Rice Field in Punjab (II) -- AT The Rice Field in Punjab (III) -- Feasibility Studies (I) -- Feasibility Studies (II) -- Feasibility Studies: Data Retrieval Plat -- Feasibility Studies: Data Retrieval Plat -- The Main Problem With Existing IoT Syste -- Internet of Things (IoT) Networks: Proto -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Rice Fields in Punjab -- Rice Harvesting -- Rice Collection -- Rice Primary Storage -- Future Plans -- Conclusions -- Map -- CHAPTER 04 -- Improved IoT Capabilities for Agricultur -- François Rivet -- Université de Bordeaux, France -- Guillaume Ferré -- Université de Bordeaux, France -- DCSS for IoT Everywhere Using -- Guillaume Ferré -- Université de Bordeaux, France -- 1. INTRODUCTION -- IoT Radio and Network links -- IoT general system -- LPWAN -- Introduction - 25% -- LEO Satellites (I) -- LEO Satellites (II) -- LEO Satellites (III) -- LEO Satellites Main Issues -- Digital Communication Techniques -- Motivations -- Contributions -- LoRa Tx/Rx Principle (Transmitter) -- LoRa Tx/Rx Principle (Receiver).
System Model (Transmitted Signal) (I) -- System Model (Transmitted Signal) (II) -- LoRa -- Frequency Error Tolerance -- LoRa Packet Structure -- CSS when Desynchronizations Occur (I) -- CSS when Desynchronizations Occur (II) -- CSS when Desynchronizations Occur (III) -- An Introduction (I) -- An Introduction (II) -- Performance (I) -- Performance (II) -- Performance (III) -- CFO Robustness (I) -- CFO Robustness (II) -- DCSS - DR Robustness (I) -- DCSS - DR Robustness (II) -- DCSS - DR Robustness (III) -- DCSS - DR Robustness (IV) -- FoV: SIC / FDMA (I) -- FoV: SIC / FDMA (I) -- Proposed Algorithm -- Strongest Signal Synchronization Algorit -- Simulation of Synthesized Signals -- Experimental Validation (I) -- Experimental Validation (II) -- Experimental Validation (III) -- Experimental Validation (IV) -- In Downlink (I) -- In Downlink (II) -- Conclusion -- 2. CSS -- 3. CSS WHEN DESYNCHRONIZATIONS OCCUR -- 4. DCSS -- 5. DR ROBUSTNESS -- 6. FoV: SIC / FDMA -- 6. CONCLUSION -- Internet of Things Device Power -- François Rivet -- Université de Bordeaux, France -- Billions of Things … -- But hardware is the key … -- It is more than data -- IoT in the countryside -- Data -- Idea -- IoT Device Operating -- Edge vs Cloud Computing -- Environmental Signals -- Regression Model (I) -- Regression Model (II) -- Regression -- Regression Model (III) -- Regression Model (IV) -- Regression Model (V) -- Regression Model (VI) -- % Error over a day -- The Order Depends on ... -- Experiment -- Digital implementation -- The Data Frame -- Coding of Coefficients -- 3-week Experiment -- 3-week Experiment Results -- 3-week Experiment Feedback -- Consumption Measurements -- Conclusion -- CHAPTER 05 -- Low Power Soc Design Flow and Methodolog -- Ronald Valenzuela -- Synopsys, Santiago, Chile -- Outline -- Applications -- Integration (I) -- The Beginning -- Integration (II).
Gordon E. Moore's Law (I) -- Gordon E. Moore's Law (II) -- About Circuits -- At the Foundry: Circuits are Printed in -- At the Foundry: Circuits are Printed in -- The Concept -- Basic Steps of Digital Design Flow (I) -- Basic Steps of Digital Design Flow (II) -- Digital IC Specification -- Logic Simulations -- Logic Synthesis (I) -- Logic Synthesis (II) -- Logic Synthesis (III) -- Logic Synthesis optimizations -- Formal Verification -- Digital Design Flow -- Physical Synthesis Steps -- Design Planning: Floorplan -- Design Planning: Power Network Synthesis -- Placement -- Clock Distribution -- Clock Tree Synthesis -- Routing -- Some Remarks Regarding Integration (I) -- Some Remarks Regarding Integration (II) -- Mainstream Optimizations -- Clock-Gating Insertion -- Self-Gating -- Architectural Optimization (I) -- Architectural Optimization (II) -- Integrated Multibit Banking and Debankin -- Power Sizing &amp -- Multi-threshold Optimizat -- Low Power Placement -- Glitch Reduction -- Dependency on Simulation Vectors -- Advanced Low Power Design Techniques -- Power Gating (Shutdown) -- Multi-Voltage -- Multi-Voltage with Shutdown -- Dynamic Voltage (and Frequency) Scaling -- Verification Challenge: Power Management -- Summary of Low Power Impact on Design Fl -- RTL Designers Need Power Intent -- UPF - A Brief History -- Defining Power Domains -- Defining Your Power Intent -- Functional Intent vs. Power Intent -- INTRODUCTION -- DESIGN FLOW -- CLOC DESIGN FLOW: PHYSICAL SYNTHESIS -- AUTOMATIC LOW POWER TECHNIQUES -- MULTI VOLTAGE WITH IEEE1801 -- CHAPTER 06 -- g/I Technique for Analog Circuit Design -- Angel Abusleme -- Pablo Walker -- Pontificia Universidad Católica de Chile -- Agribusiness Sensors and IoT -- Analog Front-ends -- Talk Outline -- ELECTRONIC AMPLIFIER DESIGN -- Analog IC Design Flow -- The Amplifier.
The Amplifier on a Feedback Configuratio.
author_facet Grimblatt, Victor.
author_variant v g vg
author_sort Grimblatt, Victor.
title Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
title_sub How the Technology Is Impacting the Agribusiness.
title_full Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
title_fullStr Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
title_full_unstemmed Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
title_auth Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
title_new Technology and Agribusiness :
title_sort technology and agribusiness : how the technology is impacting the agribusiness.
publisher River Publishers,
publishDate 2021
physical 1 online resource (351 pages)
edition 1st ed.
contents Intro -- Series Editors -- Amara Amara -- IEEE CASS President -- Yen-Kuang Chen -- VP - Technical Activities, IEEE CASS -- Yoshifumi Nishio -- VP - Regional Activities and Membership, -- Table of contents -- Introduction -- CHAPTER 01 -- IoT in the Agribusiness:Technology Tren -- Alfredo Arnaud -- Matías Miguez -- Universidad Católica del Uruguay, Montev -- RFID: Radio Frequency ID -- RFID Technologies and Classification -- RFID Tag Types (II) -- Main (at the present) passive RFID frequ -- RFID Mainstream -- RFID Applications in the Agribusiness -- RFID Tags for Animal ID -- Localization &amp -- Geolocalization -- Connectivity -- Uruguay -- Traceability Within The Fish Industry -- RFID in The Wood Industry -- RFID Based Sensors (I) -- RFID Based Sensors (II) -- Application Example: Semi-active LF Temp -- Objective - To Increase Reading Distance -- Proposed Topology - Not Only For Sensors -- Proposed Topology -- ASIC Prototype and Measurements -- IoT: Internet of Things -- IoT in the Agribusiness -- IoT Primary Market Is Still The Smart Ci -- An IoT Technology Classification (I) -- An IoT Technology Classification (II) -- An IoT Technology Classification (III) -- Single or Few Nodes… Using the TelCo -- Multi-node Network Example -- Geolocalization of Cattle… Using Farm Ar -- IoT Example: Nursery Plants Monitoring -- 3GPP Technologies -- IoT Under 3GPP For The Agribusiness Appl -- IoT Under 3GPP For The Agribusiness Appl -- Trend: Satellite IoT… Game-changer -- LoRa Based Direct Satellite Access -- ISO 11784/11785 Compliant RFID Reader -- The Reader (I) -- The Reader (II) -- Current Trend: RFID Reader -&gt -- Beyond Tra -- Current Trend: Bring the Data-Base to Th -- Bring The Data-base to The Cattleyards ( -- Bring The Data-base to The Cattleyards ( -- FAN: Farm Area Network -- Battery Powered Remote Telemetry Unit (R.
Battery Powered RTU for Ilegal Logging D -- RTU Power Consumption Profile Along Time -- Energy Consumption Measurements -- Optimal Datagram Size -- Energy Consumption Measurements Overview -- Additional HW &amp -- Communication Strategy ( -- Additional HW &amp -- Communication Strategy ( -- Partial Conclusions (I) -- Partial Conclusions (II) -- DIEstro A 5µA IoT PLATFORM FOR CATTLE HE -- AN IoT-BASED ELECTRONIC PRICE-TAG FOR FO -- SMARTNOZZLE -- CONCLUSIONS -- CHAPTER 02 -- Fruit Sector in Chile -- Álvaro Reyes -- Universidad Santo Tomás, Santiago, Chile -- Outline -- Introduction (I) -- Introduction (II) -- Introduction (III) -- Cultivated Area by Type of Farmers (Hect -- Foreign Trade Fruit Sector (I) -- Foreign Trade Fruit Sector (II) -- 1. FRUIT PRODUCTION IN CHILE -- Planted Area With Fruit Crops (Hectares) -- Chilean Fruit Exports 2008-2018 -- 2. STRENGTHS -- Strengths (I) -- Strengths (II) -- Strengths (III) -- 3. CHALLENGES -- Challenges (I) -- Challenges (II) -- Challenges (III) -- Final Remarks -- References -- CHAPTER 03 -- Internet of Things for Data Driven Preci -- Yosi Shacham Diamand -- Tel Aviv University, Tel Aviv, Israel -- 1. THE NEED FOR SENSING IN AGRICULTURE -- Need for Sensing in Agriculture (I) -- Need for Sensing in Agriculture (II) -- Need for Sensing in Agriculture (III) -- Need for Sensing in Agriculture (IV) -- Need for Sensing in Agriculture (V) -- Need for Sensing in Agriculture (VI) -- 2. AVENUES FOR SMART AND PRECISION AGRIC -- Avenues for Smart and Precision Agricult -- Avenues for Smart and Precision Agricult -- 3. SENSING IN AGRICULTURE -- Sensing in agriculture: indirect sensing -- Sensing in agriculture: direct sensing -- Sensing in Agriculture: Functional Sensi -- 4. THE DIGITAL VILLAGE -- The Idea is to Generate Data -- Site maps -- Not far from the Himalaya -- Rishikesh in the Himalayan foothills bes.
The Ganges river at the Himalaya… -- 5. OUR APPROACH -- The Digital Village. -- Goals -- Motivation -- Objectives -- Deliverable -- Novelty and Interdisciplinary Nature of -- Approach -- Possible Solutions -- Our Approach (I) -- Our Approach (II) -- 6. METHODOLOGY -- Methodology (I) -- Methodology (II) -- Methodology: Data acquisition (I) -- Methodology: Data acquisition (II) -- Methodology: Data acquisition (III) -- Methodology: pre-deployment -- Methodology: Data storage -- Methodology: Data Analysis -- Methodology -- 7. FEASIBILITY -- Pilot project -- Feasibility -- Feasibility Studies -- AT The Rice Field in Punjab (I) -- AT The Rice Field in Punjab (II) -- AT The Rice Field in Punjab (III) -- Feasibility Studies (I) -- Feasibility Studies (II) -- Feasibility Studies: Data Retrieval Plat -- Feasibility Studies: Data Retrieval Plat -- The Main Problem With Existing IoT Syste -- Internet of Things (IoT) Networks: Proto -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Rice Fields in Punjab -- Rice Harvesting -- Rice Collection -- Rice Primary Storage -- Future Plans -- Conclusions -- Map -- CHAPTER 04 -- Improved IoT Capabilities for Agricultur -- François Rivet -- Université de Bordeaux, France -- Guillaume Ferré -- Université de Bordeaux, France -- DCSS for IoT Everywhere Using -- Guillaume Ferré -- Université de Bordeaux, France -- 1. INTRODUCTION -- IoT Radio and Network links -- IoT general system -- LPWAN -- Introduction - 25% -- LEO Satellites (I) -- LEO Satellites (II) -- LEO Satellites (III) -- LEO Satellites Main Issues -- Digital Communication Techniques -- Motivations -- Contributions -- LoRa Tx/Rx Principle (Transmitter) -- LoRa Tx/Rx Principle (Receiver).
System Model (Transmitted Signal) (I) -- System Model (Transmitted Signal) (II) -- LoRa -- Frequency Error Tolerance -- LoRa Packet Structure -- CSS when Desynchronizations Occur (I) -- CSS when Desynchronizations Occur (II) -- CSS when Desynchronizations Occur (III) -- An Introduction (I) -- An Introduction (II) -- Performance (I) -- Performance (II) -- Performance (III) -- CFO Robustness (I) -- CFO Robustness (II) -- DCSS - DR Robustness (I) -- DCSS - DR Robustness (II) -- DCSS - DR Robustness (III) -- DCSS - DR Robustness (IV) -- FoV: SIC / FDMA (I) -- FoV: SIC / FDMA (I) -- Proposed Algorithm -- Strongest Signal Synchronization Algorit -- Simulation of Synthesized Signals -- Experimental Validation (I) -- Experimental Validation (II) -- Experimental Validation (III) -- Experimental Validation (IV) -- In Downlink (I) -- In Downlink (II) -- Conclusion -- 2. CSS -- 3. CSS WHEN DESYNCHRONIZATIONS OCCUR -- 4. DCSS -- 5. DR ROBUSTNESS -- 6. FoV: SIC / FDMA -- 6. CONCLUSION -- Internet of Things Device Power -- François Rivet -- Université de Bordeaux, France -- Billions of Things … -- But hardware is the key … -- It is more than data -- IoT in the countryside -- Data -- Idea -- IoT Device Operating -- Edge vs Cloud Computing -- Environmental Signals -- Regression Model (I) -- Regression Model (II) -- Regression -- Regression Model (III) -- Regression Model (IV) -- Regression Model (V) -- Regression Model (VI) -- % Error over a day -- The Order Depends on ... -- Experiment -- Digital implementation -- The Data Frame -- Coding of Coefficients -- 3-week Experiment -- 3-week Experiment Results -- 3-week Experiment Feedback -- Consumption Measurements -- Conclusion -- CHAPTER 05 -- Low Power Soc Design Flow and Methodolog -- Ronald Valenzuela -- Synopsys, Santiago, Chile -- Outline -- Applications -- Integration (I) -- The Beginning -- Integration (II).
Gordon E. Moore's Law (I) -- Gordon E. Moore's Law (II) -- About Circuits -- At the Foundry: Circuits are Printed in -- At the Foundry: Circuits are Printed in -- The Concept -- Basic Steps of Digital Design Flow (I) -- Basic Steps of Digital Design Flow (II) -- Digital IC Specification -- Logic Simulations -- Logic Synthesis (I) -- Logic Synthesis (II) -- Logic Synthesis (III) -- Logic Synthesis optimizations -- Formal Verification -- Digital Design Flow -- Physical Synthesis Steps -- Design Planning: Floorplan -- Design Planning: Power Network Synthesis -- Placement -- Clock Distribution -- Clock Tree Synthesis -- Routing -- Some Remarks Regarding Integration (I) -- Some Remarks Regarding Integration (II) -- Mainstream Optimizations -- Clock-Gating Insertion -- Self-Gating -- Architectural Optimization (I) -- Architectural Optimization (II) -- Integrated Multibit Banking and Debankin -- Power Sizing &amp -- Multi-threshold Optimizat -- Low Power Placement -- Glitch Reduction -- Dependency on Simulation Vectors -- Advanced Low Power Design Techniques -- Power Gating (Shutdown) -- Multi-Voltage -- Multi-Voltage with Shutdown -- Dynamic Voltage (and Frequency) Scaling -- Verification Challenge: Power Management -- Summary of Low Power Impact on Design Fl -- RTL Designers Need Power Intent -- UPF - A Brief History -- Defining Power Domains -- Defining Your Power Intent -- Functional Intent vs. Power Intent -- INTRODUCTION -- DESIGN FLOW -- CLOC DESIGN FLOW: PHYSICAL SYNTHESIS -- AUTOMATIC LOW POWER TECHNIQUES -- MULTI VOLTAGE WITH IEEE1801 -- CHAPTER 06 -- g/I Technique for Analog Circuit Design -- Angel Abusleme -- Pablo Walker -- Pontificia Universidad Católica de Chile -- Agribusiness Sensors and IoT -- Analog Front-ends -- Talk Outline -- ELECTRONIC AMPLIFIER DESIGN -- Analog IC Design Flow -- The Amplifier.
The Amplifier on a Feedback Configuratio.
isbn 9788770225960
callnumber-first H - Social Science
callnumber-subject HD - Industries, Land Use, Labor
callnumber-label HD9000
callnumber-sort HD 49000.5
genre Electronic books.
genre_facet Electronic books.
url https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=30169264
illustrated Not Illustrated
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dewey-tens 330 - Economics
dewey-ones 338 - Production
dewey-full 338.190285
dewey-sort 3338.190285
dewey-raw 338.190285
dewey-search 338.190285
oclc_num 1299401963
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is_hierarchy_title Technology and Agribusiness : How the Technology Is Impacting the Agribusiness.
marc_error Info : MARC8 translation shorter than ISO-8859-1, choosing MARC8. --- [ 856 : z ]
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fullrecord <?xml version="1.0" encoding="UTF-8"?><collection xmlns="http://www.loc.gov/MARC21/slim"><record><leader>11465nam a22004693i 4500</leader><controlfield tag="001">50030169264</controlfield><controlfield tag="003">MiAaPQ</controlfield><controlfield tag="005">20240229073849.0</controlfield><controlfield tag="006">m o d | </controlfield><controlfield tag="007">cr cnu||||||||</controlfield><controlfield tag="008">240229s2021 xx o ||||0 eng d</controlfield><datafield tag="020" ind1=" " ind2=" "><subfield code="a">9788770225960</subfield><subfield code="q">(electronic bk.)</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(MiAaPQ)50030169264</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(Au-PeEL)EBL30169264</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(OCoLC)1299401963</subfield></datafield><datafield tag="040" ind1=" " ind2=" "><subfield code="a">MiAaPQ</subfield><subfield code="b">eng</subfield><subfield code="e">rda</subfield><subfield code="e">pn</subfield><subfield code="c">MiAaPQ</subfield><subfield code="d">MiAaPQ</subfield></datafield><datafield tag="050" ind1=" " ind2="4"><subfield code="a">HD9000.5</subfield></datafield><datafield tag="082" ind1="0" ind2=" "><subfield code="a">338.190285</subfield></datafield><datafield tag="100" ind1="1" ind2=" "><subfield code="a">Grimblatt, Victor.</subfield></datafield><datafield tag="245" ind1="1" ind2="0"><subfield code="a">Technology and Agribusiness :</subfield><subfield code="b">How the Technology Is Impacting the Agribusiness.</subfield></datafield><datafield tag="250" ind1=" " ind2=" "><subfield code="a">1st ed.</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">Aalborg :</subfield><subfield code="b">River Publishers,</subfield><subfield code="c">2021.</subfield></datafield><datafield tag="264" ind1=" " ind2="4"><subfield code="c">©2021.</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (351 pages)</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="a">text</subfield><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="a">computer</subfield><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="a">online resource</subfield><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">Intro -- Series Editors -- Amara Amara -- IEEE CASS President -- Yen-Kuang Chen -- VP - Technical Activities, IEEE CASS -- Yoshifumi Nishio -- VP - Regional Activities and Membership, -- Table of contents -- Introduction -- CHAPTER 01 -- IoT in the Agribusiness:Technology Tren -- Alfredo Arnaud -- Matías Miguez -- Universidad Católica del Uruguay, Montev -- RFID: Radio Frequency ID -- RFID Technologies and Classification -- RFID Tag Types (II) -- Main (at the present) passive RFID frequ -- RFID Mainstream -- RFID Applications in the Agribusiness -- RFID Tags for Animal ID -- Localization &amp;amp -- Geolocalization -- Connectivity -- Uruguay -- Traceability Within The Fish Industry -- RFID in The Wood Industry -- RFID Based Sensors (I) -- RFID Based Sensors (II) -- Application Example: Semi-active LF Temp -- Objective - To Increase Reading Distance -- Proposed Topology - Not Only For Sensors -- Proposed Topology -- ASIC Prototype and Measurements -- IoT: Internet of Things -- IoT in the Agribusiness -- IoT Primary Market Is Still The Smart Ci -- An IoT Technology Classification (I) -- An IoT Technology Classification (II) -- An IoT Technology Classification (III) -- Single or Few Nodes… Using the TelCo -- Multi-node Network Example -- Geolocalization of Cattle… Using Farm Ar -- IoT Example: Nursery Plants Monitoring -- 3GPP Technologies -- IoT Under 3GPP For The Agribusiness Appl -- IoT Under 3GPP For The Agribusiness Appl -- Trend: Satellite IoT… Game-changer -- LoRa Based Direct Satellite Access -- ISO 11784/11785 Compliant RFID Reader -- The Reader (I) -- The Reader (II) -- Current Trend: RFID Reader -&amp;gt -- Beyond Tra -- Current Trend: Bring the Data-Base to Th -- Bring The Data-base to The Cattleyards ( -- Bring The Data-base to The Cattleyards ( -- FAN: Farm Area Network -- Battery Powered Remote Telemetry Unit (R.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Battery Powered RTU for Ilegal Logging D -- RTU Power Consumption Profile Along Time -- Energy Consumption Measurements -- Optimal Datagram Size -- Energy Consumption Measurements Overview -- Additional HW &amp;amp -- Communication Strategy ( -- Additional HW &amp;amp -- Communication Strategy ( -- Partial Conclusions (I) -- Partial Conclusions (II) -- DIEstro A 5µA IoT PLATFORM FOR CATTLE HE -- AN IoT-BASED ELECTRONIC PRICE-TAG FOR FO -- SMARTNOZZLE -- CONCLUSIONS -- CHAPTER 02 -- Fruit Sector in Chile -- Álvaro Reyes -- Universidad Santo Tomás, Santiago, Chile -- Outline -- Introduction (I) -- Introduction (II) -- Introduction (III) -- Cultivated Area by Type of Farmers (Hect -- Foreign Trade Fruit Sector (I) -- Foreign Trade Fruit Sector (II) -- 1. FRUIT PRODUCTION IN CHILE -- Planted Area With Fruit Crops (Hectares) -- Chilean Fruit Exports 2008-2018 -- 2. STRENGTHS -- Strengths (I) -- Strengths (II) -- Strengths (III) -- 3. CHALLENGES -- Challenges (I) -- Challenges (II) -- Challenges (III) -- Final Remarks -- References -- CHAPTER 03 -- Internet of Things for Data Driven Preci -- Yosi Shacham Diamand -- Tel Aviv University, Tel Aviv, Israel -- 1. THE NEED FOR SENSING IN AGRICULTURE -- Need for Sensing in Agriculture (I) -- Need for Sensing in Agriculture (II) -- Need for Sensing in Agriculture (III) -- Need for Sensing in Agriculture (IV) -- Need for Sensing in Agriculture (V) -- Need for Sensing in Agriculture (VI) -- 2. AVENUES FOR SMART AND PRECISION AGRIC -- Avenues for Smart and Precision Agricult -- Avenues for Smart and Precision Agricult -- 3. SENSING IN AGRICULTURE -- Sensing in agriculture: indirect sensing -- Sensing in agriculture: direct sensing -- Sensing in Agriculture: Functional Sensi -- 4. THE DIGITAL VILLAGE -- The Idea is to Generate Data -- Site maps -- Not far from the Himalaya -- Rishikesh in the Himalayan foothills bes.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">The Ganges river at the Himalaya… -- 5. OUR APPROACH -- The Digital Village. -- Goals -- Motivation -- Objectives -- Deliverable -- Novelty and Interdisciplinary Nature of -- Approach -- Possible Solutions -- Our Approach (I) -- Our Approach (II) -- 6. METHODOLOGY -- Methodology (I) -- Methodology (II) -- Methodology: Data acquisition (I) -- Methodology: Data acquisition (II) -- Methodology: Data acquisition (III) -- Methodology: pre-deployment -- Methodology: Data storage -- Methodology: Data Analysis -- Methodology -- 7. FEASIBILITY -- Pilot project -- Feasibility -- Feasibility Studies -- AT The Rice Field in Punjab (I) -- AT The Rice Field in Punjab (II) -- AT The Rice Field in Punjab (III) -- Feasibility Studies (I) -- Feasibility Studies (II) -- Feasibility Studies: Data Retrieval Plat -- Feasibility Studies: Data Retrieval Plat -- The Main Problem With Existing IoT Syste -- Internet of Things (IoT) Networks: Proto -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Internet of Things (IoT) Networks: Hybri -- Rice Fields in Punjab -- Rice Harvesting -- Rice Collection -- Rice Primary Storage -- Future Plans -- Conclusions -- Map -- CHAPTER 04 -- Improved IoT Capabilities for Agricultur -- François Rivet -- Université de Bordeaux, France -- Guillaume Ferré -- Université de Bordeaux, France -- DCSS for IoT Everywhere Using -- Guillaume Ferré -- Université de Bordeaux, France -- 1. INTRODUCTION -- IoT Radio and Network links -- IoT general system -- LPWAN -- Introduction - 25% -- LEO Satellites (I) -- LEO Satellites (II) -- LEO Satellites (III) -- LEO Satellites Main Issues -- Digital Communication Techniques -- Motivations -- Contributions -- LoRa Tx/Rx Principle (Transmitter) -- LoRa Tx/Rx Principle (Receiver).</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">System Model (Transmitted Signal) (I) -- System Model (Transmitted Signal) (II) -- LoRa -- Frequency Error Tolerance -- LoRa Packet Structure -- CSS when Desynchronizations Occur (I) -- CSS when Desynchronizations Occur (II) -- CSS when Desynchronizations Occur (III) -- An Introduction (I) -- An Introduction (II) -- Performance (I) -- Performance (II) -- Performance (III) -- CFO Robustness (I) -- CFO Robustness (II) -- DCSS - DR Robustness (I) -- DCSS - DR Robustness (II) -- DCSS - DR Robustness (III) -- DCSS - DR Robustness (IV) -- FoV: SIC / FDMA (I) -- FoV: SIC / FDMA (I) -- Proposed Algorithm -- Strongest Signal Synchronization Algorit -- Simulation of Synthesized Signals -- Experimental Validation (I) -- Experimental Validation (II) -- Experimental Validation (III) -- Experimental Validation (IV) -- In Downlink (I) -- In Downlink (II) -- Conclusion -- 2. CSS -- 3. CSS WHEN DESYNCHRONIZATIONS OCCUR -- 4. DCSS -- 5. DR ROBUSTNESS -- 6. FoV: SIC / FDMA -- 6. CONCLUSION -- Internet of Things Device Power -- François Rivet -- Université de Bordeaux, France -- Billions of Things … -- But hardware is the key … -- It is more than data -- IoT in the countryside -- Data -- Idea -- IoT Device Operating -- Edge vs Cloud Computing -- Environmental Signals -- Regression Model (I) -- Regression Model (II) -- Regression -- Regression Model (III) -- Regression Model (IV) -- Regression Model (V) -- Regression Model (VI) -- % Error over a day -- The Order Depends on ... -- Experiment -- Digital implementation -- The Data Frame -- Coding of Coefficients -- 3-week Experiment -- 3-week Experiment Results -- 3-week Experiment Feedback -- Consumption Measurements -- Conclusion -- CHAPTER 05 -- Low Power Soc Design Flow and Methodolog -- Ronald Valenzuela -- Synopsys, Santiago, Chile -- Outline -- Applications -- Integration (I) -- The Beginning -- Integration (II).</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Gordon E. Moore's Law (I) -- Gordon E. Moore's Law (II) -- About Circuits -- At the Foundry: Circuits are Printed in -- At the Foundry: Circuits are Printed in -- The Concept -- Basic Steps of Digital Design Flow (I) -- Basic Steps of Digital Design Flow (II) -- Digital IC Specification -- Logic Simulations -- Logic Synthesis (I) -- Logic Synthesis (II) -- Logic Synthesis (III) -- Logic Synthesis optimizations -- Formal Verification -- Digital Design Flow -- Physical Synthesis Steps -- Design Planning: Floorplan -- Design Planning: Power Network Synthesis -- Placement -- Clock Distribution -- Clock Tree Synthesis -- Routing -- Some Remarks Regarding Integration (I) -- Some Remarks Regarding Integration (II) -- Mainstream Optimizations -- Clock-Gating Insertion -- Self-Gating -- Architectural Optimization (I) -- Architectural Optimization (II) -- Integrated Multibit Banking and Debankin -- Power Sizing &amp;amp -- Multi-threshold Optimizat -- Low Power Placement -- Glitch Reduction -- Dependency on Simulation Vectors -- Advanced Low Power Design Techniques -- Power Gating (Shutdown) -- Multi-Voltage -- Multi-Voltage with Shutdown -- Dynamic Voltage (and Frequency) Scaling -- Verification Challenge: Power Management -- Summary of Low Power Impact on Design Fl -- RTL Designers Need Power Intent -- UPF - A Brief History -- Defining Power Domains -- Defining Your Power Intent -- Functional Intent vs. Power Intent -- INTRODUCTION -- DESIGN FLOW -- CLOC DESIGN FLOW: PHYSICAL SYNTHESIS -- AUTOMATIC LOW POWER TECHNIQUES -- MULTI VOLTAGE WITH IEEE1801 -- CHAPTER 06 -- g/I Technique for Analog Circuit Design -- Angel Abusleme -- Pablo Walker -- Pontificia Universidad Católica de Chile -- Agribusiness Sensors and IoT -- Analog Front-ends -- Talk Outline -- ELECTRONIC AMPLIFIER DESIGN -- Analog IC Design Flow -- The Amplifier.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">The Amplifier on a Feedback Configuratio.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">This book discusses the major problems in agribusiness and technologies that can be applied to solve and improve such issues. Agribusiness covers topics such as arable farming, dairy farming, fruits, vegetables, meat, etc. Each domain has different needs that can be addressed through smart agriculture technologies such as circuits and systems.</subfield></datafield><datafield tag="588" ind1=" " ind2=" "><subfield code="a">Description based on publisher supplied metadata and other sources.</subfield></datafield><datafield tag="590" ind1=" " ind2=" "><subfield code="a">Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. </subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Internet of things.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Agricultural industries--Technological innovations.</subfield></datafield><datafield tag="655" ind1=" " ind2="4"><subfield code="a">Electronic books.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Grimblatt, Victor</subfield><subfield code="t">Technology and Agribusiness: How the Technology Is Impacting the Agribusiness</subfield><subfield code="d">Aalborg : River Publishers,c2021</subfield></datafield><datafield tag="797" ind1="2" ind2=" "><subfield code="a">ProQuest (Firm)</subfield></datafield><datafield tag="856" ind1="4" ind2="0"><subfield code="u">https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=30169264</subfield><subfield code="z">Click to View</subfield></datafield></record></collection>

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