際際滷shows by User: umakantgphatre / http://www.slideshare.net/images/logo.gif 際際滷shows by User: umakantgphatre / Wed, 19 Jun 2024 03:07:11 GMT 際際滷Share feed for 際際滷shows by User: umakantgphatre PWM Arduino Experiment for Engineering pra /slideshow/pwm-arduino-experiment-for-engineering-pra/269755487 pwmarduino-240619030712-db683236
Basics of PWM (Pulse Width Modulation) The Fading example demonstrates the use of analog output (PWM) to fade an LED. It is available in the File->Sketchbook->Examples->Analog menu of the Arduino software. Pulse Width Modulation, or PWM, is a technique for getting analog results with digital means. Digital control is used to create a square wave, a signal switched between on and off. This on-off pattern can simulate voltages in between the full Vcc of the board (e.g., 5 V on UNO, 3.3 V on a MKR board) and off (0 Volts) by changing the portion of the time the signal spends on versus the time that the signal spends off. The duration of "on time" is called the pulse width. To get varying analog values, you change, or modulate, that pulse width. If you repeat this on-off pattern fast enough with an LED for example, the result is as if the signal is a steady voltage between 0 and Vcc controlling the brightness of the LED]]>
Basics of PWM (Pulse Width Modulation) The Fading example demonstrates the use of analog output (PWM) to fade an LED. It is available in the File->Sketchbook->Examples->Analog menu of the Arduino software. Pulse Width Modulation, or PWM, is a technique for getting analog results with digital means. Digital control is used to create a square wave, a signal switched between on and off. This on-off pattern can simulate voltages in between the full Vcc of the board (e.g., 5 V on UNO, 3.3 V on a MKR board) and off (0 Volts) by changing the portion of the time the signal spends on versus the time that the signal spends off. The duration of "on time" is called the pulse width. To get varying analog values, you change, or modulate, that pulse width. If you repeat this on-off pattern fast enough with an LED for example, the result is as if the signal is a steady voltage between 0 and Vcc controlling the brightness of the LED]]> Wed, 19 Jun 2024 03:07:11 GMT /slideshow/pwm-arduino-experiment-for-engineering-pra/269755487 umakantgphatre@slideshare.net(umakantgphatre) PWM Arduino Experiment for Engineering pra umakantgphatre Basics of PWM (Pulse Width Modulation) The Fading example demonstrates the use of analog output (PWM) to fade an LED. It is available in the File->Sketchbook->Examples->Analog menu of the Arduino software. Pulse Width Modulation, or PWM, is a technique for getting analog results with digital means. Digital control is used to create a square wave, a signal switched between on and off. This on-off pattern can simulate voltages in between the full Vcc of the board (e.g., 5 V on UNO, 3.3 V on a MKR board) and off (0 Volts) by changing the portion of the time the signal spends on versus the time that the signal spends off. The duration of "on time" is called the pulse width. To get varying analog values, you change, or modulate, that pulse width. If you repeat this on-off pattern fast enough with an LED for example, the result is as if the signal is a steady voltage between 0 and Vcc controlling the brightness of the LED <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pwmarduino-240619030712-db683236-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Basics of PWM (Pulse Width Modulation) The Fading example demonstrates the use of analog output (PWM) to fade an LED. It is available in the File-&gt;Sketchbook-&gt;Examples-&gt;Analog menu of the Arduino software. Pulse Width Modulation, or PWM, is a technique for getting analog results with digital means. Digital control is used to create a square wave, a signal switched between on and off. This on-off pattern can simulate voltages in between the full Vcc of the board (e.g., 5 V on UNO, 3.3 V on a MKR board) and off (0 Volts) by changing the portion of the time the signal spends on versus the time that the signal spends off. The duration of &quot;on time&quot; is called the pulse width. To get varying analog values, you change, or modulate, that pulse width. If you repeat this on-off pattern fast enough with an LED for example, the result is as if the signal is a steady voltage between 0 and Vcc controlling the brightness of the LED
PWM Arduino Experiment for Engineering pra from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 41 0 https://cdn.slidesharecdn.com/ss_thumbnails/pwmarduino-240619030712-db683236-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Artificial Intelligence (AI) application in Agriculture Area /slideshow/artificial-intelligence-ai-application-in-agriculture-area/258289267 aiagri-230607113222-3e2082e1
The Future Agriculture Industry with Artificial Intelligence (AI) based TechnologyAuthor: Umakant Bhaskar Gohatre AI (Artificial Intelligence) in agriculture refers to the use of advanced technologies and algorithms to improve various aspects of farming and crop management. It involves leveraging data, machine learning, computer vision, and other AI techniques to optimize agricultural processes, increase productivity, reduce resource waste, and make informed decisions. Here are some key applications of AI in agriculture 1. Crop Monitoring and Disease Detection: AI can analyze data from various sources such as satellite imagery, drones, and IoT sensors to monitor crop health and detect diseases, pests, or nutrient deficiencies. Machine learning algorithms can process large datasets to identify patterns and indicators of crop stress, enabling early intervention and targeted treatment. 2. Precision Farming: AI-based systems can collect and analyze data on soil conditions, weather patterns, and historical crop performance to optimize planting, irrigation, fertilization, and pesticide application. By integrating data from sensors, drones, and other devices, AI can provide real-time recommendations for precise and site-specific farming practices, reducing costs and environmental impact. 3. Autonomous Farming: Powered robots and autonomous vehicles can perform tasks such as planting, harvesting, and weeding with precision and efficiency. Computer vision algorithms enable machines to identify and differentiate between crops, weeds, and other objects in the field, allowing for targeted actions and selective treatments. 4. Yield Prediction and Forecasting: By analysing historical data, weather patterns, and other factors, AI algorithms can predict crop yields, helping farmers make better decisions regarding planting schedules, resource allocation, and market planning. 5. Livestock Monitoring AI-based systems can monitor the health and behavior of livestock using computer vision and sensor technologies. Facial recognition and behavioral analysis can identify individual animals, detect signs of distress or illness, and optimize feeding and breeding programs. 6. Supply Chain Optimization: AI can optimize the logistics and supply chain management in agriculture, improving traceability, reducing waste, and enhancing efficiency. Predictive analytics can help anticipate market demand, optimize transportation routes, and streamline inventory management. 7. Decision Support Systems: AI can provide farmers with decision support tools, analyzing complex data and providing actionable insights. By considering multiple factors such as weather, market prices, and historical data, AI systems can recommend optimal planting strategies, input management, and risk mitigation measures. The integration of AI in agriculture holds great potential to address the challenges faced by the industry,]]>
The Future Agriculture Industry with Artificial Intelligence (AI) based TechnologyAuthor: Umakant Bhaskar Gohatre AI (Artificial Intelligence) in agriculture refers to the use of advanced technologies and algorithms to improve various aspects of farming and crop management. It involves leveraging data, machine learning, computer vision, and other AI techniques to optimize agricultural processes, increase productivity, reduce resource waste, and make informed decisions. Here are some key applications of AI in agriculture 1. Crop Monitoring and Disease Detection: AI can analyze data from various sources such as satellite imagery, drones, and IoT sensors to monitor crop health and detect diseases, pests, or nutrient deficiencies. Machine learning algorithms can process large datasets to identify patterns and indicators of crop stress, enabling early intervention and targeted treatment. 2. Precision Farming: AI-based systems can collect and analyze data on soil conditions, weather patterns, and historical crop performance to optimize planting, irrigation, fertilization, and pesticide application. By integrating data from sensors, drones, and other devices, AI can provide real-time recommendations for precise and site-specific farming practices, reducing costs and environmental impact. 3. Autonomous Farming: Powered robots and autonomous vehicles can perform tasks such as planting, harvesting, and weeding with precision and efficiency. Computer vision algorithms enable machines to identify and differentiate between crops, weeds, and other objects in the field, allowing for targeted actions and selective treatments. 4. Yield Prediction and Forecasting: By analysing historical data, weather patterns, and other factors, AI algorithms can predict crop yields, helping farmers make better decisions regarding planting schedules, resource allocation, and market planning. 5. Livestock Monitoring AI-based systems can monitor the health and behavior of livestock using computer vision and sensor technologies. Facial recognition and behavioral analysis can identify individual animals, detect signs of distress or illness, and optimize feeding and breeding programs. 6. Supply Chain Optimization: AI can optimize the logistics and supply chain management in agriculture, improving traceability, reducing waste, and enhancing efficiency. Predictive analytics can help anticipate market demand, optimize transportation routes, and streamline inventory management. 7. Decision Support Systems: AI can provide farmers with decision support tools, analyzing complex data and providing actionable insights. By considering multiple factors such as weather, market prices, and historical data, AI systems can recommend optimal planting strategies, input management, and risk mitigation measures. The integration of AI in agriculture holds great potential to address the challenges faced by the industry,]]> Wed, 07 Jun 2023 11:32:21 GMT /slideshow/artificial-intelligence-ai-application-in-agriculture-area/258289267 umakantgphatre@slideshare.net(umakantgphatre) Artificial Intelligence (AI) application in Agriculture Area umakantgphatre The Future Agriculture Industry with Artificial Intelligence (AI) based TechnologyAuthor: Umakant Bhaskar Gohatre AI (Artificial Intelligence) in agriculture refers to the use of advanced technologies and algorithms to improve various aspects of farming and crop management. It involves leveraging data, machine learning, computer vision, and other AI techniques to optimize agricultural processes, increase productivity, reduce resource waste, and make informed decisions. Here are some key applications of AI in agriculture 1. Crop Monitoring and Disease Detection: AI can analyze data from various sources such as satellite imagery, drones, and IoT sensors to monitor crop health and detect diseases, pests, or nutrient deficiencies. Machine learning algorithms can process large datasets to identify patterns and indicators of crop stress, enabling early intervention and targeted treatment. 2. Precision Farming: AI-based systems can collect and analyze data on soil conditions, weather patterns, and historical crop performance to optimize planting, irrigation, fertilization, and pesticide application. By integrating data from sensors, drones, and other devices, AI can provide real-time recommendations for precise and site-specific farming practices, reducing costs and environmental impact. 3. Autonomous Farming: Powered robots and autonomous vehicles can perform tasks such as planting, harvesting, and weeding with precision and efficiency. Computer vision algorithms enable machines to identify and differentiate between crops, weeds, and other objects in the field, allowing for targeted actions and selective treatments. 4. Yield Prediction and Forecasting: By analysing historical data, weather patterns, and other factors, AI algorithms can predict crop yields, helping farmers make better decisions regarding planting schedules, resource allocation, and market planning. 5. Livestock Monitoring AI-based systems can monitor the health and behavior of livestock using computer vision and sensor technologies. Facial recognition and behavioral analysis can identify individual animals, detect signs of distress or illness, and optimize feeding and breeding programs. 6. Supply Chain Optimization: AI can optimize the logistics and supply chain management in agriculture, improving traceability, reducing waste, and enhancing efficiency. Predictive analytics can help anticipate market demand, optimize transportation routes, and streamline inventory management. 7. Decision Support Systems: AI can provide farmers with decision support tools, analyzing complex data and providing actionable insights. By considering multiple factors such as weather, market prices, and historical data, AI systems can recommend optimal planting strategies, input management, and risk mitigation measures. The integration of AI in agriculture holds great potential to address the challenges faced by the industry, <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/aiagri-230607113222-3e2082e1-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> The Future Agriculture Industry with Artificial Intelligence (AI) based TechnologyAuthor: Umakant Bhaskar Gohatre AI (Artificial Intelligence) in agriculture refers to the use of advanced technologies and algorithms to improve various aspects of farming and crop management. It involves leveraging data, machine learning, computer vision, and other AI techniques to optimize agricultural processes, increase productivity, reduce resource waste, and make informed decisions. Here are some key applications of AI in agriculture 1. Crop Monitoring and Disease Detection: AI can analyze data from various sources such as satellite imagery, drones, and IoT sensors to monitor crop health and detect diseases, pests, or nutrient deficiencies. Machine learning algorithms can process large datasets to identify patterns and indicators of crop stress, enabling early intervention and targeted treatment. 2. Precision Farming: AI-based systems can collect and analyze data on soil conditions, weather patterns, and historical crop performance to optimize planting, irrigation, fertilization, and pesticide application. By integrating data from sensors, drones, and other devices, AI can provide real-time recommendations for precise and site-specific farming practices, reducing costs and environmental impact. 3. Autonomous Farming: Powered robots and autonomous vehicles can perform tasks such as planting, harvesting, and weeding with precision and efficiency. Computer vision algorithms enable machines to identify and differentiate between crops, weeds, and other objects in the field, allowing for targeted actions and selective treatments. 4. Yield Prediction and Forecasting: By analysing historical data, weather patterns, and other factors, AI algorithms can predict crop yields, helping farmers make better decisions regarding planting schedules, resource allocation, and market planning. 5. Livestock Monitoring AI-based systems can monitor the health and behavior of livestock using computer vision and sensor technologies. Facial recognition and behavioral analysis can identify individual animals, detect signs of distress or illness, and optimize feeding and breeding programs. 6. Supply Chain Optimization: AI can optimize the logistics and supply chain management in agriculture, improving traceability, reducing waste, and enhancing efficiency. Predictive analytics can help anticipate market demand, optimize transportation routes, and streamline inventory management. 7. Decision Support Systems: AI can provide farmers with decision support tools, analyzing complex data and providing actionable insights. By considering multiple factors such as weather, market prices, and historical data, AI systems can recommend optimal planting strategies, input management, and risk mitigation measures. The integration of AI in agriculture holds great potential to address the challenges faced by the industry,
Artificial Intelligence (AI) application in Agriculture Area from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 104 0 https://cdn.slidesharecdn.com/ss_thumbnails/aiagri-230607113222-3e2082e1-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 VLSI Design Book CMOS_Circuit_Design__Layout__and_Simulation /umakantgphatre/vlsi-design-book-cmoscircuitdesignlayoutandsimulation cmoscircuitdesignlayoutandsimulation3rdedition-230512105726-b855800a
CMOS (complementary metal oxide semiconductor) technology continues to be the dominant technology for fabricating integrated circuits (ICs or chips). This dominance will likely continue for the next 25 years and perhaps even longer. Why? CMOS technology is reliable, manufacturable, low power, low cost, and, perhaps most importantly, scalable. The fact that silicon integrated circuit technology is scalable was observed and described in 1965 by Intel founder Gordon Moore. His observations are now referred to as Moore's law and state that the number of devices on a chip will double every 18 to 24 months. While originally not specific to CMOS, Moore's law has been fulfilled over the years by scaling down the feature size in CMOS technology. Whereas the gate lengths of early CMOS transistors were in the micrometer range (long-channel devices) the feature sizes of current CMOS devices are in the nanometer range (short-channel devices). To encompass both the long- and short-channel CMOS technologies in this book, a two-path approach to custom CMOS integrated circuit design is adopted. Design techniques are developed for both and then compared. This comparison gives readers deep insight into the circuit design process. While the square-law equations used to describe MOSFET operation that students learn in an introductory course in microelectronics can be used for analog design in a long-channel CMOS process they are not useful when designing in short-channel, or nanometer, CMOS technology. The behavior of the devices in a nanometer CMOS process is quite complex. Simple equations to describe the devices' behavior are not possible. Rather electrical plots are used to estimate biasing points and operating behavior. It is still useful, however, for the student to use mathematical rigor when learning circuit analysis and design and, hence, the reason for the two-path approach. Hand calculations can be performed using a long-channel CMOS technology with the results then used to describe how to design in a nano-CMOS process. ]]>
CMOS (complementary metal oxide semiconductor) technology continues to be the dominant technology for fabricating integrated circuits (ICs or chips). This dominance will likely continue for the next 25 years and perhaps even longer. Why? CMOS technology is reliable, manufacturable, low power, low cost, and, perhaps most importantly, scalable. The fact that silicon integrated circuit technology is scalable was observed and described in 1965 by Intel founder Gordon Moore. His observations are now referred to as Moore's law and state that the number of devices on a chip will double every 18 to 24 months. While originally not specific to CMOS, Moore's law has been fulfilled over the years by scaling down the feature size in CMOS technology. Whereas the gate lengths of early CMOS transistors were in the micrometer range (long-channel devices) the feature sizes of current CMOS devices are in the nanometer range (short-channel devices). To encompass both the long- and short-channel CMOS technologies in this book, a two-path approach to custom CMOS integrated circuit design is adopted. Design techniques are developed for both and then compared. This comparison gives readers deep insight into the circuit design process. While the square-law equations used to describe MOSFET operation that students learn in an introductory course in microelectronics can be used for analog design in a long-channel CMOS process they are not useful when designing in short-channel, or nanometer, CMOS technology. The behavior of the devices in a nanometer CMOS process is quite complex. Simple equations to describe the devices' behavior are not possible. Rather electrical plots are used to estimate biasing points and operating behavior. It is still useful, however, for the student to use mathematical rigor when learning circuit analysis and design and, hence, the reason for the two-path approach. Hand calculations can be performed using a long-channel CMOS technology with the results then used to describe how to design in a nano-CMOS process. ]]> Fri, 12 May 2023 10:57:26 GMT /umakantgphatre/vlsi-design-book-cmoscircuitdesignlayoutandsimulation umakantgphatre@slideshare.net(umakantgphatre) VLSI Design Book CMOS_Circuit_Design__Layout__and_Simulation umakantgphatre CMOS (complementary metal oxide semiconductor) technology continues to be the dominant technology for fabricating integrated circuits (ICs or chips). This dominance will likely continue for the next 25 years and perhaps even longer. Why? CMOS technology is reliable, manufacturable, low power, low cost, and, perhaps most importantly, scalable. The fact that silicon integrated circuit technology is scalable was observed and described in 1965 by Intel founder Gordon Moore. His observations are now referred to as Moore's law and state that the number of devices on a chip will double every 18 to 24 months. While originally not specific to CMOS, Moore's law has been fulfilled over the years by scaling down the feature size in CMOS technology. Whereas the gate lengths of early CMOS transistors were in the micrometer range (long-channel devices) the feature sizes of current CMOS devices are in the nanometer range (short-channel devices). To encompass both the long- and short-channel CMOS technologies in this book, a two-path approach to custom CMOS integrated circuit design is adopted. Design techniques are developed for both and then compared. This comparison gives readers deep insight into the circuit design process. While the square-law equations used to describe MOSFET operation that students learn in an introductory course in microelectronics can be used for analog design in a long-channel CMOS process they are not useful when designing in short-channel, or nanometer, CMOS technology. The behavior of the devices in a nanometer CMOS process is quite complex. Simple equations to describe the devices' behavior are not possible. Rather electrical plots are used to estimate biasing points and operating behavior. It is still useful, however, for the student to use mathematical rigor when learning circuit analysis and design and, hence, the reason for the two-path approach. Hand calculations can be performed using a long-channel CMOS technology with the results then used to describe how to design in a nano-CMOS process. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/cmoscircuitdesignlayoutandsimulation3rdedition-230512105726-b855800a-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> CMOS (complementary metal oxide semiconductor) technology continues to be the dominant technology for fabricating integrated circuits (ICs or chips). This dominance will likely continue for the next 25 years and perhaps even longer. Why? CMOS technology is reliable, manufacturable, low power, low cost, and, perhaps most importantly, scalable. The fact that silicon integrated circuit technology is scalable was observed and described in 1965 by Intel founder Gordon Moore. His observations are now referred to as Moore&#39;s law and state that the number of devices on a chip will double every 18 to 24 months. While originally not specific to CMOS, Moore&#39;s law has been fulfilled over the years by scaling down the feature size in CMOS technology. Whereas the gate lengths of early CMOS transistors were in the micrometer range (long-channel devices) the feature sizes of current CMOS devices are in the nanometer range (short-channel devices). To encompass both the long- and short-channel CMOS technologies in this book, a two-path approach to custom CMOS integrated circuit design is adopted. Design techniques are developed for both and then compared. This comparison gives readers deep insight into the circuit design process. While the square-law equations used to describe MOSFET operation that students learn in an introductory course in microelectronics can be used for analog design in a long-channel CMOS process they are not useful when designing in short-channel, or nanometer, CMOS technology. The behavior of the devices in a nanometer CMOS process is quite complex. Simple equations to describe the devices&#39; behavior are not possible. Rather electrical plots are used to estimate biasing points and operating behavior. It is still useful, however, for the student to use mathematical rigor when learning circuit analysis and design and, hence, the reason for the two-path approach. Hand calculations can be performed using a long-channel CMOS technology with the results then used to describe how to design in a nano-CMOS process.
VLSI Design Book CMOS_Circuit_Design__Layout__and_Simulation from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 236 0 https://cdn.slidesharecdn.com/ss_thumbnails/cmoscircuitdesignlayoutandsimulation3rdedition-230512105726-b855800a-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Question Bank: Network Management in Telecommunication /slideshow/question-bank-network-management-in-telecommunication/257759810 nmtqbumakantgohatre-230510063813-6d8f2ca4
Question Bank: Network Management in TelecommunicationModule 1: Introduction of Network Management 1] What problem would you expect the NMS to resolve, and how? 2] What are the Challenges of IT Manager? 3] Explain trouble ticket administration? 4] Draw Network Management Dumb bell architecture. 5] In absence of a sophisticated NMS, explain the methods used for Management in an organization. 6] List some common network problems. 7] Why NMS is required? 8] Draw the Dumbbell architecture for Network management. 9] What is the goal of Network Management?]]>
Question Bank: Network Management in TelecommunicationModule 1: Introduction of Network Management 1] What problem would you expect the NMS to resolve, and how? 2] What are the Challenges of IT Manager? 3] Explain trouble ticket administration? 4] Draw Network Management Dumb bell architecture. 5] In absence of a sophisticated NMS, explain the methods used for Management in an organization. 6] List some common network problems. 7] Why NMS is required? 8] Draw the Dumbbell architecture for Network management. 9] What is the goal of Network Management?]]> Wed, 10 May 2023 06:38:13 GMT /slideshow/question-bank-network-management-in-telecommunication/257759810 umakantgphatre@slideshare.net(umakantgphatre) Question Bank: Network Management in Telecommunication umakantgphatre Question Bank: Network Management in TelecommunicationModule 1: Introduction of Network Management 1] What problem would you expect the NMS to resolve, and how? 2] What are the Challenges of IT Manager? 3] Explain trouble ticket administration? 4] Draw Network Management Dumb bell architecture. 5] In absence of a sophisticated NMS, explain the methods used for Management in an organization. 6] List some common network problems. 7] Why NMS is required? 8] Draw the Dumbbell architecture for Network management. 9] What is the goal of Network Management? <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/nmtqbumakantgohatre-230510063813-6d8f2ca4-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Question Bank: Network Management in TelecommunicationModule 1: Introduction of Network Management 1] What problem would you expect the NMS to resolve, and how? 2] What are the Challenges of IT Manager? 3] Explain trouble ticket administration? 4] Draw Network Management Dumb bell architecture. 5] In absence of a sophisticated NMS, explain the methods used for Management in an organization. 6] List some common network problems. 7] Why NMS is required? 8] Draw the Dumbbell architecture for Network management. 9] What is the goal of Network Management?
Question Bank: Network Management in Telecommunication from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 451 0 https://cdn.slidesharecdn.com/ss_thumbnails/nmtqbumakantgohatre-230510063813-6d8f2ca4-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 INTRODUCTION TO CYBER LAW The Concept of Cyberspace Cyber law Cyber crime.pdf /slideshow/introduction-to-cyber-law-the-concept-of-cyberspace-cyber-law-cyber-crimepdf/257504197 introductiontocyberlawtheconceptofcyberspacecyberlawcybercrime-230421112711-eff69997
Pre 1990: People are not connected 1990: Connecting People to Information1990: Connecting People to Information 2000: Connecting People to People2000: Connecting People to Peopl]]>
Pre 1990: People are not connected 1990: Connecting People to Information1990: Connecting People to Information 2000: Connecting People to People2000: Connecting People to Peopl]]> Fri, 21 Apr 2023 11:27:10 GMT /slideshow/introduction-to-cyber-law-the-concept-of-cyberspace-cyber-law-cyber-crimepdf/257504197 umakantgphatre@slideshare.net(umakantgphatre) INTRODUCTION TO CYBER LAW The Concept of Cyberspace Cyber law Cyber crime.pdf umakantgphatre Pre 1990: People are not connected 1990: Connecting People to Information1990: Connecting People to Information 2000: Connecting People to People2000: Connecting People to Peopl <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/introductiontocyberlawtheconceptofcyberspacecyberlawcybercrime-230421112711-eff69997-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Pre 1990: People are not connected 1990: Connecting People to Information1990: Connecting People to Information 2000: Connecting People to People2000: Connecting People to Peopl
INTRODUCTION TO CYBER LAW The Concept of Cyberspace Cyber law Cyber crime.pdf from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 858 0 https://cdn.slidesharecdn.com/ss_thumbnails/introductiontocyberlawtheconceptofcyberspacecyberlawcybercrime-230421112711-eff69997-thumbnail.jpg?width=120&height=120&fit=bounds presentation Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 LRU_Replacement-Policy.pdf /slideshow/lrureplacementpolicypdf/257503763 lrureplacement-policy-230421104404-7d9b9644
LRU Replacement Policy The Least Recently Used replacement policy chooses to replace the page which has not been referenced for the longest time. This policy assumes the recent past will approximate the immediate future. The operating system keeps track of when each page was referenced by recording the time of reference or by maintaining a stack of references]]>
LRU Replacement Policy The Least Recently Used replacement policy chooses to replace the page which has not been referenced for the longest time. This policy assumes the recent past will approximate the immediate future. The operating system keeps track of when each page was referenced by recording the time of reference or by maintaining a stack of references]]> Fri, 21 Apr 2023 10:44:04 GMT /slideshow/lrureplacementpolicypdf/257503763 umakantgphatre@slideshare.net(umakantgphatre) LRU_Replacement-Policy.pdf umakantgphatre LRU Replacement Policy The Least Recently Used replacement policy chooses to replace the page which has not been referenced for the longest time. This policy assumes the recent past will approximate the immediate future. The operating system keeps track of when each page was referenced by recording the time of reference or by maintaining a stack of references <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/lrureplacement-policy-230421104404-7d9b9644-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> LRU Replacement Policy The Least Recently Used replacement policy chooses to replace the page which has not been referenced for the longest time. This policy assumes the recent past will approximate the immediate future. The operating system keeps track of when each page was referenced by recording the time of reference or by maintaining a stack of references
LRU_Replacement-Policy.pdf from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 25 0 https://cdn.slidesharecdn.com/ss_thumbnails/lrureplacement-policy-230421104404-7d9b9644-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Network Management Principles and Practice - 2nd Edition (2010)_2.pdf /slideshow/network-management-principles-and-practice-2nd-edition-20102pdf/255597895 3-networkmanagementprinciplesandpractice-2ndedition20102-230130113556-e95d18c3
Table of Contents Copyright Endorsements Preface About the Author Plitt J: Background Oiapt束 1. Data Communications and Networlmmunicatlon Network Section 1.3. Distributed CCmputing Environment Section 1.4. TCP/IP-Based Networks: Internet and Intranet Section 1.5. Communication Protocols and Standards Section 1.6. Networks, Systems, and Services Section 1.7. case Histories on Network, System, ard Servics Management Section 1.8. Challenges of IT Managers Section 1.9. Network Management : Goals, Organization, and Functions Section 1.10. Network Management Architecture and Organization Section 1.11. Network Management Perspectives Section 1.1.2. NMS Platform Section 1.13. CUrrent Status and Future cl Network Mana{jement Summary Exercises Chapter 2. Review of Information Nelwor1< and Technolog]]>
Table of Contents Copyright Endorsements Preface About the Author Plitt J: Background Oiapt束 1. Data Communications and Networlmmunicatlon Network Section 1.3. Distributed CCmputing Environment Section 1.4. TCP/IP-Based Networks: Internet and Intranet Section 1.5. Communication Protocols and Standards Section 1.6. Networks, Systems, and Services Section 1.7. case Histories on Network, System, ard Servics Management Section 1.8. Challenges of IT Managers Section 1.9. Network Management : Goals, Organization, and Functions Section 1.10. Network Management Architecture and Organization Section 1.11. Network Management Perspectives Section 1.1.2. NMS Platform Section 1.13. CUrrent Status and Future cl Network Mana{jement Summary Exercises Chapter 2. Review of Information Nelwor1< and Technolog]]> Mon, 30 Jan 2023 11:35:56 GMT /slideshow/network-management-principles-and-practice-2nd-edition-20102pdf/255597895 umakantgphatre@slideshare.net(umakantgphatre) Network Management Principles and Practice - 2nd Edition (2010)_2.pdf umakantgphatre Table of Contents Copyright Endorsements Preface About the Author Plitt J: Background Oiapt束 1. Data Communications and Networl< Management Overview Section 1.1. Analogy cl Telephone Network Management Section 1.2. Data (Computer) and Telea>mmunicatlon Network Section 1.3. Distributed CCmputing Environment Section 1.4. TCP/IP-Based Networks: Internet and Intranet Section 1.5. Communication Protocols and Standards Section 1.6. Networks, Systems, and Services Section 1.7. case Histories on Network, System, ard Servics Management Section 1.8. Challenges of IT Managers Section 1.9. Network Management : Goals, Organization, and Functions Section 1.10. Network Management Architecture and Organization Section 1.11. Network Management Perspectives Section 1.1.2. NMS Platform Section 1.13. CUrrent Status and Future cl Network Mana{jement Summary Exercises Chapter 2. Review of Information Nelwor1< and Technolog <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/3-networkmanagementprinciplesandpractice-2ndedition20102-230130113556-e95d18c3-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Table of Contents Copyright Endorsements Preface About the Author Plitt J: Background Oiapt束 1. Data Communications and Networlmmunicatlon Network Section 1.3. Distributed CCmputing Environment Section 1.4. TCP/IP-Based Networks: Internet and Intranet Section 1.5. Communication Protocols and Standards Section 1.6. Networks, Systems, and Services Section 1.7. case Histories on Network, System, ard Servics Management Section 1.8. Challenges of IT Managers Section 1.9. Network Management : Goals, Organization, and Functions Section 1.10. Network Management Architecture and Organization Section 1.11. Network Management Perspectives Section 1.1.2. NMS Platform Section 1.13. CUrrent Status and Future cl Network Mana{jement Summary Exercises Chapter 2. Review of Information Nelwor1&lt; and Technolog
Network Management Principles and Practice - 2nd Edition (2010)_2.pdf from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 2236 0 https://cdn.slidesharecdn.com/ss_thumbnails/3-networkmanagementprinciplesandpractice-2ndedition20102-230130113556-e95d18c3-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Euler Method Details /slideshow/euler-method-details/252482246 eulermethoddetails-220809105254-853a9e97
Euler's method is a numerical method to solve first order first degree differential equation with a given initial value. It is the most basic explicit method for numerical integration of ordinary differential equations and is the simplest RungeKutta method. The Euler method is a first-order method, which means that the local error (error per step) is proportional to the square of the step size, and the global error (error at a given time) is proportional to the step size. The Euler method often serves as the basis to construct more complex methods, e.g., predictorcorrector method ]]>
Euler's method is a numerical method to solve first order first degree differential equation with a given initial value. It is the most basic explicit method for numerical integration of ordinary differential equations and is the simplest RungeKutta method. The Euler method is a first-order method, which means that the local error (error per step) is proportional to the square of the step size, and the global error (error at a given time) is proportional to the step size. The Euler method often serves as the basis to construct more complex methods, e.g., predictorcorrector method ]]> Tue, 09 Aug 2022 10:52:54 GMT /slideshow/euler-method-details/252482246 umakantgphatre@slideshare.net(umakantgphatre) Euler Method Details umakantgphatre Euler's method is a numerical method to solve first order first degree differential equation with a given initial value. It is the most basic explicit method for numerical integration of ordinary differential equations and is the simplest RungeKutta method. The Euler method is a first-order method, which means that the local error (error per step) is proportional to the square of the step size, and the global error (error at a given time) is proportional to the step size. The Euler method often serves as the basis to construct more complex methods, e.g., predictorcorrector method <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/eulermethoddetails-220809105254-853a9e97-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Euler&#39;s method is a numerical method to solve first order first degree differential equation with a given initial value. It is the most basic explicit method for numerical integration of ordinary differential equations and is the simplest RungeKutta method. The Euler method is a first-order method, which means that the local error (error per step) is proportional to the square of the step size, and the global error (error at a given time) is proportional to the step size. The Euler method often serves as the basis to construct more complex methods, e.g., predictorcorrector method
Euler Method Details from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 268 0 https://cdn.slidesharecdn.com/ss_thumbnails/eulermethoddetails-220809105254-853a9e97-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Mini Project fo BE Engineering students /umakantgphatre/mini-project-fo-be-engineering-students listofminiprojectsheet1-220809104008-5ff6ab78
Mini Project fo BE Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Water Level Controller using 8051 Microcontroller: Here we are designing the circuit which is used to detect and control the water level automatically in overhead tank using 8051 microcontroller. It is used in industries to control the liquid level automatically. Password Based Door Lock System using 8051 Microcontroller: This system demonstrates a password based door lock system wherein once the correct code or password is entered, the door is opened and the concerned person is allowed access to the secured area. After some time, the door would be closed. Read this post completely to get more information. Car Parking Guard Circuit Using Infrared Sensor: This circuit helps the person in the driving seat in such a way that it gives an alarm if there is any obstacle or a wall while parking or while driving in reverse. It is very useful in our real life. Battery Charger Circuit Using SCR: Here is the circuit diagram of battery charger circuit using Silicon Controlled Rectifier. SCR can be used in half wave rectifier, full wave rectifier, inverter circuits, power control circuits, etc. Interfacing GPS with 8051 Microcontroller: In this interfacing of GPS with 8051 circuit, GPS module calculates the position by reading the signals that are transmitted by satellites. Speed Control of DC Motor Using Pulse Width Modulation: This pulse width modulation technique is the more efficient way to proceed to manage the speed of our DC motor manually. Metal Detector Circuit: This is a simple metal detector circuit which is very useful for checking the person in shopping malls, hotels, cinema halls to ensure that person is not carrying any explosive metals or illegal things like guns, bombs etc.]]>
Mini Project fo BE Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Water Level Controller using 8051 Microcontroller: Here we are designing the circuit which is used to detect and control the water level automatically in overhead tank using 8051 microcontroller. It is used in industries to control the liquid level automatically. Password Based Door Lock System using 8051 Microcontroller: This system demonstrates a password based door lock system wherein once the correct code or password is entered, the door is opened and the concerned person is allowed access to the secured area. After some time, the door would be closed. Read this post completely to get more information. Car Parking Guard Circuit Using Infrared Sensor: This circuit helps the person in the driving seat in such a way that it gives an alarm if there is any obstacle or a wall while parking or while driving in reverse. It is very useful in our real life. Battery Charger Circuit Using SCR: Here is the circuit diagram of battery charger circuit using Silicon Controlled Rectifier. SCR can be used in half wave rectifier, full wave rectifier, inverter circuits, power control circuits, etc. Interfacing GPS with 8051 Microcontroller: In this interfacing of GPS with 8051 circuit, GPS module calculates the position by reading the signals that are transmitted by satellites. Speed Control of DC Motor Using Pulse Width Modulation: This pulse width modulation technique is the more efficient way to proceed to manage the speed of our DC motor manually. Metal Detector Circuit: This is a simple metal detector circuit which is very useful for checking the person in shopping malls, hotels, cinema halls to ensure that person is not carrying any explosive metals or illegal things like guns, bombs etc.]]> Tue, 09 Aug 2022 10:40:08 GMT /umakantgphatre/mini-project-fo-be-engineering-students umakantgphatre@slideshare.net(umakantgphatre) Mini Project fo BE Engineering students umakantgphatre Mini Project fo BE Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Water Level Controller using 8051 Microcontroller: Here we are designing the circuit which is used to detect and control the water level automatically in overhead tank using 8051 microcontroller. It is used in industries to control the liquid level automatically. Password Based Door Lock System using 8051 Microcontroller: This system demonstrates a password based door lock system wherein once the correct code or password is entered, the door is opened and the concerned person is allowed access to the secured area. After some time, the door would be closed. Read this post completely to get more information. Car Parking Guard Circuit Using Infrared Sensor: This circuit helps the person in the driving seat in such a way that it gives an alarm if there is any obstacle or a wall while parking or while driving in reverse. It is very useful in our real life. Battery Charger Circuit Using SCR: Here is the circuit diagram of battery charger circuit using Silicon Controlled Rectifier. SCR can be used in half wave rectifier, full wave rectifier, inverter circuits, power control circuits, etc. Interfacing GPS with 8051 Microcontroller: In this interfacing of GPS with 8051 circuit, GPS module calculates the position by reading the signals that are transmitted by satellites. Speed Control of DC Motor Using Pulse Width Modulation: This pulse width modulation technique is the more efficient way to proceed to manage the speed of our DC motor manually. Metal Detector Circuit: This is a simple metal detector circuit which is very useful for checking the person in shopping malls, hotels, cinema halls to ensure that person is not carrying any explosive metals or illegal things like guns, bombs etc. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/listofminiprojectsheet1-220809104008-5ff6ab78-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Mini Project fo BE Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Water Level Controller using 8051 Microcontroller: Here we are designing the circuit which is used to detect and control the water level automatically in overhead tank using 8051 microcontroller. It is used in industries to control the liquid level automatically. Password Based Door Lock System using 8051 Microcontroller: This system demonstrates a password based door lock system wherein once the correct code or password is entered, the door is opened and the concerned person is allowed access to the secured area. After some time, the door would be closed. Read this post completely to get more information. Car Parking Guard Circuit Using Infrared Sensor: This circuit helps the person in the driving seat in such a way that it gives an alarm if there is any obstacle or a wall while parking or while driving in reverse. It is very useful in our real life. Battery Charger Circuit Using SCR: Here is the circuit diagram of battery charger circuit using Silicon Controlled Rectifier. SCR can be used in half wave rectifier, full wave rectifier, inverter circuits, power control circuits, etc. Interfacing GPS with 8051 Microcontroller: In this interfacing of GPS with 8051 circuit, GPS module calculates the position by reading the signals that are transmitted by satellites. Speed Control of DC Motor Using Pulse Width Modulation: This pulse width modulation technique is the more efficient way to proceed to manage the speed of our DC motor manually. Metal Detector Circuit: This is a simple metal detector circuit which is very useful for checking the person in shopping malls, hotels, cinema halls to ensure that person is not carrying any explosive metals or illegal things like guns, bombs etc.
Mini Project fo BE Engineering students from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 22 0 https://cdn.slidesharecdn.com/ss_thumbnails/listofminiprojectsheet1-220809104008-5ff6ab78-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Mini Project for Engineering Students BE or Btech Engineering students /slideshow/mini-project-for-engineering-students-be-or-btech-engineering-students/252482113 listofminiprojectsheet2-220809103729-aa5029e3
Mini Project for Engineering Students BE or Btech Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Fire Alarm with Siren Sound: This circuit alerts us when there is a fire accident at home by ringing a siren sound instead of a buzzer. Mosquito Repellent Circuit: Here is the simple electronic mosquito repellent circuit which can produce ultrasound in the frequency range of 20-38 kHz, which can scare away mosquitoes. Electronic Letter Box: This is a simple circuit which helps in finding out any letter dropped in our box by stopping the LED lights attached in this circuit. Dummy Alarm Circuit: The main principle of the circuit is to flash an LED for every 5 seconds. The circuit consists of 7555 timer IC as main component. DTMF Based Home Automation System Circuit: This is a simple and very useful circuit in our real life named DTMF controlled home appliances system. It helps to control the home appliances using DTMF technology. Ding Dong Sound Generator Circuit: This is ding dong sound generator circuit is designed using 555 timer IC in astable mode. It can be used as doorbell. With some modifications, it can be used to produce different sounds. Read this post for complete details. Digital Voltmeter Circuit using ICL7107: Here we designed a analog to digital converter working as a digital voltmeter using a low power three and half digit A/D converter ICL7107 having internal 7 segment decoders, display drivers, a reference and a clock. Digital Temperature Sensor: The main principle of this circuit is to display the digital temperature value. These are mainly used in environmental applications. Digital Stopwatch Circuit: This is a simple circuit that displays count from 0 to 59, representing a 60 second time interval. It consists of a 555 timer to produce the clock pulses and two counter ICs to carry out the counting operation. Basic Logic Gates Using NAND Gate: We are all well known that NOT, AND, OR are the basic logic gates. Here we have shown how to design these basic logic gates using one of the universal gates NAND Gate.]]>
Mini Project for Engineering Students BE or Btech Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Fire Alarm with Siren Sound: This circuit alerts us when there is a fire accident at home by ringing a siren sound instead of a buzzer. Mosquito Repellent Circuit: Here is the simple electronic mosquito repellent circuit which can produce ultrasound in the frequency range of 20-38 kHz, which can scare away mosquitoes. Electronic Letter Box: This is a simple circuit which helps in finding out any letter dropped in our box by stopping the LED lights attached in this circuit. Dummy Alarm Circuit: The main principle of the circuit is to flash an LED for every 5 seconds. The circuit consists of 7555 timer IC as main component. DTMF Based Home Automation System Circuit: This is a simple and very useful circuit in our real life named DTMF controlled home appliances system. It helps to control the home appliances using DTMF technology. Ding Dong Sound Generator Circuit: This is ding dong sound generator circuit is designed using 555 timer IC in astable mode. It can be used as doorbell. With some modifications, it can be used to produce different sounds. Read this post for complete details. Digital Voltmeter Circuit using ICL7107: Here we designed a analog to digital converter working as a digital voltmeter using a low power three and half digit A/D converter ICL7107 having internal 7 segment decoders, display drivers, a reference and a clock. Digital Temperature Sensor: The main principle of this circuit is to display the digital temperature value. These are mainly used in environmental applications. Digital Stopwatch Circuit: This is a simple circuit that displays count from 0 to 59, representing a 60 second time interval. It consists of a 555 timer to produce the clock pulses and two counter ICs to carry out the counting operation. Basic Logic Gates Using NAND Gate: We are all well known that NOT, AND, OR are the basic logic gates. Here we have shown how to design these basic logic gates using one of the universal gates NAND Gate.]]> Tue, 09 Aug 2022 10:37:29 GMT /slideshow/mini-project-for-engineering-students-be-or-btech-engineering-students/252482113 umakantgphatre@slideshare.net(umakantgphatre) Mini Project for Engineering Students BE or Btech Engineering students umakantgphatre Mini Project for Engineering Students BE or Btech Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Fire Alarm with Siren Sound: This circuit alerts us when there is a fire accident at home by ringing a siren sound instead of a buzzer. Mosquito Repellent Circuit: Here is the simple electronic mosquito repellent circuit which can produce ultrasound in the frequency range of 20-38 kHz, which can scare away mosquitoes. Electronic Letter Box: This is a simple circuit which helps in finding out any letter dropped in our box by stopping the LED lights attached in this circuit. Dummy Alarm Circuit: The main principle of the circuit is to flash an LED for every 5 seconds. The circuit consists of 7555 timer IC as main component. DTMF Based Home Automation System Circuit: This is a simple and very useful circuit in our real life named DTMF controlled home appliances system. It helps to control the home appliances using DTMF technology. Ding Dong Sound Generator Circuit: This is ding dong sound generator circuit is designed using 555 timer IC in astable mode. It can be used as doorbell. With some modifications, it can be used to produce different sounds. Read this post for complete details. Digital Voltmeter Circuit using ICL7107: Here we designed a analog to digital converter working as a digital voltmeter using a low power three and half digit A/D converter ICL7107 having internal 7 segment decoders, display drivers, a reference and a clock. Digital Temperature Sensor: The main principle of this circuit is to display the digital temperature value. These are mainly used in environmental applications. Digital Stopwatch Circuit: This is a simple circuit that displays count from 0 to 59, representing a 60 second time interval. It consists of a 555 timer to produce the clock pulses and two counter ICs to carry out the counting operation. Basic Logic Gates Using NAND Gate: We are all well known that NOT, AND, OR are the basic logic gates. Here we have shown how to design these basic logic gates using one of the universal gates NAND Gate. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/listofminiprojectsheet2-220809103729-aa5029e3-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Mini Project for Engineering Students BE or Btech Engineering students Smt. Indira Gandhi College of Engineering, Navi Mumbai Department of Electronics and Telecommunication Engineering Subject In charge: Umakant Bhaskar Gohatre, Assistant Professor List of Mini Projects: Fire Alarm with Siren Sound: This circuit alerts us when there is a fire accident at home by ringing a siren sound instead of a buzzer. Mosquito Repellent Circuit: Here is the simple electronic mosquito repellent circuit which can produce ultrasound in the frequency range of 20-38 kHz, which can scare away mosquitoes. Electronic Letter Box: This is a simple circuit which helps in finding out any letter dropped in our box by stopping the LED lights attached in this circuit. Dummy Alarm Circuit: The main principle of the circuit is to flash an LED for every 5 seconds. The circuit consists of 7555 timer IC as main component. DTMF Based Home Automation System Circuit: This is a simple and very useful circuit in our real life named DTMF controlled home appliances system. It helps to control the home appliances using DTMF technology. Ding Dong Sound Generator Circuit: This is ding dong sound generator circuit is designed using 555 timer IC in astable mode. It can be used as doorbell. With some modifications, it can be used to produce different sounds. Read this post for complete details. Digital Voltmeter Circuit using ICL7107: Here we designed a analog to digital converter working as a digital voltmeter using a low power three and half digit A/D converter ICL7107 having internal 7 segment decoders, display drivers, a reference and a clock. Digital Temperature Sensor: The main principle of this circuit is to display the digital temperature value. These are mainly used in environmental applications. Digital Stopwatch Circuit: This is a simple circuit that displays count from 0 to 59, representing a 60 second time interval. It consists of a 555 timer to produce the clock pulses and two counter ICs to carry out the counting operation. Basic Logic Gates Using NAND Gate: We are all well known that NOT, AND, OR are the basic logic gates. Here we have shown how to design these basic logic gates using one of the universal gates NAND Gate.
Mini Project for Engineering Students BE or Btech Engineering students from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 25 0 https://cdn.slidesharecdn.com/ss_thumbnails/listofminiprojectsheet2-220809103729-aa5029e3-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Ballistics Detsils /slideshow/ballistics-detsils/252482070 ballisticsdetails-220809103339-5ecf9097
Ballistics is the field of mechanics that worries with the starting, flight conduct and effect impacts of shots, particularly gone weapon weapons, for example, slugs, unguided bombs, rockets or something like that; the science or craft of structuring and quickening shots in order to accomplish an ideal execution. A ballistic body is a free-moving body with energy which can be liable to powers, for example, the powers applied by pressurized gases from a weapon barrel or a pushing spout, typical power by rifling, and gravity and air haul during flight. A ballistic rocket is a rocket that is guided distinctly during the generally concise beginning period of fueled flight and the direction is in this way represented by the laws of traditional mechanics; rather than (for instance) a voyage rocket which is efficiently guided in controlled flight like a fixed-wing air ship.Projectile launchers Throwing is the starting of a shot by hand. Albeit some different creatures can toss, people are curiously great hurlers because of their high expertise and great planning abilities, and it is accepted this is a developed attribute. Proof of human tossing goes back 2 million years. The 90 mph tossing velocity found in numerous competitors far surpasses the speed at which chimpanzees can toss things, which is around 20 mph. This capacity mirrors the capacity of the human shoulder muscles and ligaments to store flexibility until it is expected to drive an item. Sling ]]>
Ballistics is the field of mechanics that worries with the starting, flight conduct and effect impacts of shots, particularly gone weapon weapons, for example, slugs, unguided bombs, rockets or something like that; the science or craft of structuring and quickening shots in order to accomplish an ideal execution. A ballistic body is a free-moving body with energy which can be liable to powers, for example, the powers applied by pressurized gases from a weapon barrel or a pushing spout, typical power by rifling, and gravity and air haul during flight. A ballistic rocket is a rocket that is guided distinctly during the generally concise beginning period of fueled flight and the direction is in this way represented by the laws of traditional mechanics; rather than (for instance) a voyage rocket which is efficiently guided in controlled flight like a fixed-wing air ship.Projectile launchers Throwing is the starting of a shot by hand. Albeit some different creatures can toss, people are curiously great hurlers because of their high expertise and great planning abilities, and it is accepted this is a developed attribute. Proof of human tossing goes back 2 million years. The 90 mph tossing velocity found in numerous competitors far surpasses the speed at which chimpanzees can toss things, which is around 20 mph. This capacity mirrors the capacity of the human shoulder muscles and ligaments to store flexibility until it is expected to drive an item. Sling ]]> Tue, 09 Aug 2022 10:33:38 GMT /slideshow/ballistics-detsils/252482070 umakantgphatre@slideshare.net(umakantgphatre) Ballistics Detsils umakantgphatre Ballistics is the field of mechanics that worries with the starting, flight conduct and effect impacts of shots, particularly gone weapon weapons, for example, slugs, unguided bombs, rockets or something like that; the science or craft of structuring and quickening shots in order to accomplish an ideal execution. A ballistic body is a free-moving body with energy which can be liable to powers, for example, the powers applied by pressurized gases from a weapon barrel or a pushing spout, typical power by rifling, and gravity and air haul during flight. A ballistic rocket is a rocket that is guided distinctly during the generally concise beginning period of fueled flight and the direction is in this way represented by the laws of traditional mechanics; rather than (for instance) a voyage rocket which is efficiently guided in controlled flight like a fixed-wing air ship.Projectile launchers Throwing is the starting of a shot by hand. Albeit some different creatures can toss, people are curiously great hurlers because of their high expertise and great planning abilities, and it is accepted this is a developed attribute. Proof of human tossing goes back 2 million years. The 90 mph tossing velocity found in numerous competitors far surpasses the speed at which chimpanzees can toss things, which is around 20 mph. This capacity mirrors the capacity of the human shoulder muscles and ligaments to store flexibility until it is expected to drive an item. Sling <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/ballisticsdetails-220809103339-5ecf9097-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Ballistics is the field of mechanics that worries with the starting, flight conduct and effect impacts of shots, particularly gone weapon weapons, for example, slugs, unguided bombs, rockets or something like that; the science or craft of structuring and quickening shots in order to accomplish an ideal execution. A ballistic body is a free-moving body with energy which can be liable to powers, for example, the powers applied by pressurized gases from a weapon barrel or a pushing spout, typical power by rifling, and gravity and air haul during flight. A ballistic rocket is a rocket that is guided distinctly during the generally concise beginning period of fueled flight and the direction is in this way represented by the laws of traditional mechanics; rather than (for instance) a voyage rocket which is efficiently guided in controlled flight like a fixed-wing air ship.Projectile launchers Throwing is the starting of a shot by hand. Albeit some different creatures can toss, people are curiously great hurlers because of their high expertise and great planning abilities, and it is accepted this is a developed attribute. Proof of human tossing goes back 2 million years. The 90 mph tossing velocity found in numerous competitors far surpasses the speed at which chimpanzees can toss things, which is around 20 mph. This capacity mirrors the capacity of the human shoulder muscles and ligaments to store flexibility until it is expected to drive an item. Sling
Ballistics Detsils from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 24 0 https://cdn.slidesharecdn.com/ss_thumbnails/ballisticsdetails-220809103339-5ecf9097-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 VLSI Design_LAB MANUAL By Umakant Gohatre /umakantgphatre/vlsi-designlab-manual-by-umakant-gohatre vlsidesignlabmanualumakantgohatre-220720103822-88e8b41f
Lab manual for Educational Purpose, Subject: VLSI Design ]]>
Lab manual for Educational Purpose, Subject: VLSI Design ]]> Wed, 20 Jul 2022 10:38:22 GMT /umakantgphatre/vlsi-designlab-manual-by-umakant-gohatre umakantgphatre@slideshare.net(umakantgphatre) VLSI Design_LAB MANUAL By Umakant Gohatre umakantgphatre Lab manual for Educational Purpose, Subject: VLSI Design <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/vlsidesignlabmanualumakantgohatre-220720103822-88e8b41f-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Lab manual for Educational Purpose, Subject: VLSI Design
VLSI Design_LAB MANUAL By Umakant Gohatre from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 99 0 https://cdn.slidesharecdn.com/ss_thumbnails/vlsidesignlabmanualumakantgohatre-220720103822-88e8b41f-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Cryptography and Network Security /slideshow/cryptography-and-network-security-249882293/249882293 ch02-210729080347
Cryptography and Network Security introduction ]]>
Cryptography and Network Security introduction ]]> Thu, 29 Jul 2021 08:03:46 GMT /slideshow/cryptography-and-network-security-249882293/249882293 umakantgphatre@slideshare.net(umakantgphatre) Cryptography and Network Security umakantgphatre Cryptography and Network Security introduction <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/ch02-210729080347-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Cryptography and Network Security introduction
Cryptography and Network Security from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
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Introduction Cyber Crime - What Is Cyber Crime? - Types Of Cyber Crime Cyber Security - What Is Cyber Security? - Top Seven Cyber Safety Actions - Cyber Safety At Work & Hom]]>
Introduction Cyber Crime - What Is Cyber Crime? - Types Of Cyber Crime Cyber Security - What Is Cyber Security? - Top Seven Cyber Safety Actions - Cyber Safety At Work & Hom]]> Sun, 18 Jul 2021 05:16:40 GMT /slideshow/cyber-crime-cyber-security-introduction-umakant-bhaskar-gohatre/249786176 umakantgphatre@slideshare.net(umakantgphatre) cyber crime, Cyber Security, Introduction, Umakant Bhaskar Gohatre umakantgphatre Introduction Cyber Crime - What Is Cyber Crime? - Types Of Cyber Crime Cyber Security - What Is Cyber Security? - Top Seven Cyber Safety Actions - Cyber Safety At Work & Hom <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/module1cybercrime-210718051640-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Introduction Cyber Crime - What Is Cyber Crime? - Types Of Cyber Crime Cyber Security - What Is Cyber Security? - Top Seven Cyber Safety Actions - Cyber Safety At Work &amp; Hom
cyber crime, Cyber Security, Introduction, Umakant Bhaskar Gohatre from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 259 0 https://cdn.slidesharecdn.com/ss_thumbnails/module1cybercrime-210718051640-thumbnail.jpg?width=120&height=120&fit=bounds presentation Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Image Compression, Introduction Data Compression/ Data compression, modelling and coding,Image Compression /slideshow/image-compression-introduction-data-compression-data-compression-modelling-and-codingimage-compression/249786148 module1imagecompressiona-210718045328
Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.]]>
Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.]]> Sun, 18 Jul 2021 04:53:28 GMT /slideshow/image-compression-introduction-data-compression-data-compression-modelling-and-codingimage-compression/249786148 umakantgphatre@slideshare.net(umakantgphatre) Image Compression, Introduction Data Compression/ Data compression, modelling and coding,Image Compression umakantgphatre Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/module1imagecompressiona-210718045328-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.
Image Compression, Introduction Data Compression/ Data compression, modelling and coding,Image Compression from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 291 0 https://cdn.slidesharecdn.com/ss_thumbnails/module1imagecompressiona-210718045328-thumbnail.jpg?width=120&height=120&fit=bounds presentation Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Introduction Data Compression/ Data compression, modelling and coding,Image Compression /slideshow/introduction-data-compression-data-compression-modelling-and-codingimage-compression/249786143 module1datacompressionintroduction-210718044748
Introduction to Data Compression Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.]]>
Introduction to Data Compression Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.]]> Sun, 18 Jul 2021 04:47:47 GMT /slideshow/introduction-data-compression-data-compression-modelling-and-codingimage-compression/249786143 umakantgphatre@slideshare.net(umakantgphatre) Introduction Data Compression/ Data compression, modelling and coding,Image Compression umakantgphatre Introduction to Data Compression Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/module1datacompressionintroduction-210718044748-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Introduction to Data Compression Data compression, modelling and coding, Lossless and Lossy Compression, Arithmetic Coding Decoding, Dictionary Based Compression, Sliding Window Compression: LZ-77, LZ-78, LZW. 1.2 Image Compression DCT, JPEG, JPEG LS, Differential Lossless Compression, DPCM, JPEG 2000 Standards.
Introduction Data Compression/ Data compression, modelling and coding,Image Compression from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
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Python overview]]>
Python overview]]> Fri, 12 Jul 2019 15:21:09 GMT /slideshow/python-overview-155176885/155176885 umakantgphatre@slideshare.net(umakantgphatre) Python overview umakantgphatre Python overview <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pythonoverview-190712152109-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Python overview
Python overview from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 182 1 https://cdn.slidesharecdn.com/ss_thumbnails/pythonoverview-190712152109-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Python numbers /slideshow/python-numbers/155176883 pythonnumbers-190712152108
Python numbers]]>
Python numbers]]> Fri, 12 Jul 2019 15:21:08 GMT /slideshow/python-numbers/155176883 umakantgphatre@slideshare.net(umakantgphatre) Python numbers umakantgphatre Python numbers <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pythonnumbers-190712152108-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Python numbers
Python numbers from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 843 1 https://cdn.slidesharecdn.com/ss_thumbnails/pythonnumbers-190712152108-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Python networking /slideshow/python-networking/155176878 pythonnetworking-190712152108
Python networking]]>
Python networking]]> Fri, 12 Jul 2019 15:21:08 GMT /slideshow/python-networking/155176878 umakantgphatre@slideshare.net(umakantgphatre) Python networking umakantgphatre Python networking <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pythonnetworking-190712152108-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Python networking
Python networking from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 396 2 https://cdn.slidesharecdn.com/ss_thumbnails/pythonnetworking-190712152108-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 Python multithreading /slideshow/python-multithreading-155176874/155176874 pythonmultithreading-190712152108
Python multithreading]]>
Python multithreading]]> Fri, 12 Jul 2019 15:21:07 GMT /slideshow/python-multithreading-155176874/155176874 umakantgphatre@slideshare.net(umakantgphatre) Python multithreading umakantgphatre Python multithreading <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pythonmultithreading-190712152108-thumbnail.jpg?width=120&amp;height=120&amp;fit=bounds" /><br> Python multithreading
Python multithreading from Smt. Indira Gandhi College of Engineering, Navi Mumbai, Mumbai
]]> 621 1 https://cdn.slidesharecdn.com/ss_thumbnails/pythonmultithreading-190712152108-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post http://activitystrea.ms/schema/1.0/posted 0 https://cdn.slidesharecdn.com/profile-photo-umakantgphatre-48x48.jpg?cb=1718766394 Skill #1: Knowledge of the core subject Skill #2: Application of the knowledge Skill #3: Information Literacy Skill #4: Analytical & Creative thinking Skill #5: Multi-disciplinary exposure Skill #6: Acquaintance with Computers & IT Skill #7: Familiarity with Industry Standards Skill #8: Passion for learning The last and the most important characteristic that will make you not only a better engineer but a better person is the never-ending spirit for learning. https://cdn.slidesharecdn.com/ss_thumbnails/pwmarduino-240619030712-db683236-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/pwm-arduino-experiment-for-engineering-pra/269755487 PWM Arduino Experiment... https://cdn.slidesharecdn.com/ss_thumbnails/aiagri-230607113222-3e2082e1-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/artificial-intelligence-ai-application-in-agriculture-area/258289267 Artificial Intelligenc... https://cdn.slidesharecdn.com/ss_thumbnails/cmoscircuitdesignlayoutandsimulation3rdedition-230512105726-b855800a-thumbnail.jpg?width=320&height=320&fit=bounds umakantgphatre/vlsi-design-book-cmoscircuitdesignlayoutandsimulation VLSI Design Book CMOS_...