This document discusses hacks and cheats for the game Star Wars Battlefront. It mentions an undetected hack featuring an aimbot and ESP that can be downloaded now. It also discusses upcoming aimbot hacks in November and hacks for Battlefront 2 that include features like aimbot, no recoil, aim spot, auto fire and more. It notes that some hacks only support 64-bit operating systems. Finally, it discusses players improvising life hacks in Battlefront 2 and the need for better anti-cheat systems to prevent actual hacks and cheats.
The University of Illinois uses a locally developed metasearch service, "Easy Search". We have recently added the ability to query the metasearch program as RESTful web service, allowing library content to be promoted to external web pages such as departmental web presences or courseware.
Introduction to method overloading & method overriding in java hdmHarshal Misalkar
This document introduces method overloading and method overriding in Java. Method overloading allows a class to have multiple methods with the same name but different parameters. It increases readability. Method overriding allows a subclass to provide a specific implementation of a method declared in the parent class. It is used for runtime polymorphism where the method being called is determined by the object type. The document provides examples of method overloading by changing number/type of arguments and of method overriding where the subclass overrides the parent's display method.
This document discusses polymorphism in C# through method overloading and overriding. It shows how to create a base DrawingObject class that can be inherited by Line, Circle, and Square classes, where each subclass overrides the Draw method to output its type. The Main method creates instances of each subclass and calls their Draw methods to demonstrate polymorphism. The document also compares abstract classes and interfaces, noting that abstract classes can contain implemented methods while interfaces only contain signatures, and interfaces allow multiple inheritance while abstract classes do not.
This document discusses inheritance in Java programming. It defines inheritance as an "is-a" relationship between a superclass and subclass where the subclass is a more specific version of the superclass. The key concepts covered include method overloading, where methods can have the same name but different signatures; method overriding, where subclasses can provide their own implementation of a method in the superclass; and dynamic method dispatch, which determines which version of an overridden method to call at runtime based on the object type.
Polymorphism in java, method overloading and method overridingJavaTportal
Polymorphism come from the two Greek words ‘poly’ meaning many and ‘morphs” meaning forms. The ability to exist in different form is called polymorphism. The same variable or method can perform different tasks; the programmer has the advantage of writing flexible code.
Presented by: N.V.RajaSekhar Reddy
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This document provides an overview of reservoir engineering fundamentals including:
- Three types of reservoir fluids based on compressibility: incompressible, slightly compressible, and compressible.
- Three flow regimes in reservoirs: steady-state, unsteady-state, and pseudosteady-state.
- Common reservoir geometries that influence fluid flow including radial, linear, spherical, and hemispherical.
- Darcy's law and its applications to steady-state fluid flow in reservoirs, including for different fluid types and geometries.
This document discusses hacks and cheats for the game Star Wars Battlefront. It mentions an undetected hack featuring an aimbot and ESP that can be downloaded now. It also discusses upcoming aimbot hacks in November and hacks for Battlefront 2 that include features like aimbot, no recoil, aim spot, auto fire and more. It notes that some hacks only support 64-bit operating systems. Finally, it discusses players improvising life hacks in Battlefront 2 and the need for better anti-cheat systems to prevent actual hacks and cheats.
The University of Illinois uses a locally developed metasearch service, "Easy Search". We have recently added the ability to query the metasearch program as RESTful web service, allowing library content to be promoted to external web pages such as departmental web presences or courseware.
Introduction to method overloading & method overriding in java hdmHarshal Misalkar
This document introduces method overloading and method overriding in Java. Method overloading allows a class to have multiple methods with the same name but different parameters. It increases readability. Method overriding allows a subclass to provide a specific implementation of a method declared in the parent class. It is used for runtime polymorphism where the method being called is determined by the object type. The document provides examples of method overloading by changing number/type of arguments and of method overriding where the subclass overrides the parent's display method.
This document discusses polymorphism in C# through method overloading and overriding. It shows how to create a base DrawingObject class that can be inherited by Line, Circle, and Square classes, where each subclass overrides the Draw method to output its type. The Main method creates instances of each subclass and calls their Draw methods to demonstrate polymorphism. The document also compares abstract classes and interfaces, noting that abstract classes can contain implemented methods while interfaces only contain signatures, and interfaces allow multiple inheritance while abstract classes do not.
This document discusses inheritance in Java programming. It defines inheritance as an "is-a" relationship between a superclass and subclass where the subclass is a more specific version of the superclass. The key concepts covered include method overloading, where methods can have the same name but different signatures; method overriding, where subclasses can provide their own implementation of a method in the superclass; and dynamic method dispatch, which determines which version of an overridden method to call at runtime based on the object type.
Polymorphism in java, method overloading and method overridingJavaTportal
Polymorphism come from the two Greek words ‘poly’ meaning many and ‘morphs” meaning forms. The ability to exist in different form is called polymorphism. The same variable or method can perform different tasks; the programmer has the advantage of writing flexible code.
Presented by: N.V.RajaSekhar Reddy
www.technolamp.co.in
Want more interesting...
Watch and Like us @ https://www.facebook.com/Technolamp.co.in
subscribe videos @ http://www.youtube.com/user/nvrajasekhar
This document provides an overview of reservoir engineering fundamentals including:
- Three types of reservoir fluids based on compressibility: incompressible, slightly compressible, and compressible.
- Three flow regimes in reservoirs: steady-state, unsteady-state, and pseudosteady-state.
- Common reservoir geometries that influence fluid flow including radial, linear, spherical, and hemispherical.
- Darcy's law and its applications to steady-state fluid flow in reservoirs, including for different fluid types and geometries.
This document provides an overview of methods for calculating natural gas properties including:
1. Empirical correlations for calculating gas compressibility factors such as Hall-Yarborough, Dranchuk-Abu-Kassem, and Dranchuk-Purvis-Robinson.
2. Calculation of gas formation volume factor and gas expansion factor from gas compressibility factors and properties.
3. Empirical correlations for calculating gas viscosity including Carr-Kobayashi-Burrows and Lee-Gonzalez-Eakin.
This document provides an overview of methods for calculating properties of reservoir fluids including gas and crude oil. It discusses empirical correlations for calculating z-factors, gas properties like compressibility and viscosity, and crude oil properties like density, solubility of dissolved gas, and bubble point pressure. The key empirical correlations presented for estimating gas solubility (Rs) and methods for determining bubble point pressure are Standing, Vasquez-Beggs, Glaso, Marhoun, Petrosky-Farshad, and correlations based on experimental PVT data.
This document provides an overview of reservoir fluid properties including:
1. Crude oil properties such as density, gas solubility, bubble point pressure, formation volume factor, compressibility, and correlations to calculate these properties.
2. Water properties including water formation volume factor, viscosity, gas solubility in water, and water isothermal compressibility.
3. The total formation volume factor and viscosity of crude oil are also discussed along with definitions of dead-oil, saturated-oil, and undersaturated oil viscosities.
The document discusses procedures and results from differential liberation experiments used to characterize reservoir fluids. Key points:
- Differential liberation experiments slowly depressurize a reservoir fluid sample to measure properties like oil and gas volumes, gas composition, and solution gas-oil ratio at different pressures.
- Properties measured include formation volumes factors (Bo and Bg) which indicate volume changes from reservoir to surface conditions, and solution gas-oil ratio (Rs) which provides ratio of gas to oil volumes.
- Trends in Bo, Bg and Rs with pressure provide insight into fluid behavior during production.
This document provides an overview of three primary reservoir fluid property experiments: constant-mass expansion (CME), constant-volume depletion (CVD), and differential liberation (DL). It describes the objectives, procedures, and key results of each experiment. The CME experiment measures formation volume factor, compressibility, and relative fluid volumes at varying pressures. The CVD simulates reservoir depletion, measuring properties like liquid dropout and gas compositions. The DL characterizes differential gas liberation from oil during pressure decline.
This document provides an overview of methods for calculating reservoir fluid properties, including crude oil and water properties. It discusses calculating the total formation volume factor (Bt) using correlations like Standing's and Glaso's. It also covers calculating crude oil viscosity, including dead-oil viscosity using Beal's correlation, saturated oil viscosity using Chew-Connally, and undersaturated oil viscosity using Vasquez-Beggs. The document provides equations and discusses experimental data ranges for various fluid property correlations.
This document covers reservoir engineering concepts related to petroleum reservoirs. It discusses the classification of oil and gas reservoirs based on phase behavior and pressure-temperature relationships. It also summarizes key reservoir fluid properties for both gas and crude oil, including compressibility factors, density, molecular weight, and formation volume factors. The behaviors of real gases are contrasted with ideal gases and methods for determining compressibility factors are presented.
This document outlines the syllabus for a Reservoir Engineering 1 course. The 3 credit hour course is intended for sophomore and junior petroleum engineering students and covers fundamental reservoir engineering concepts and their practical applications. Lectures will be divided into two 50-slide presentations with a short break. Students will be assessed based on class activities, a midterm exam, and a final exam. The course schedule lists 16 lectures covering topics like petroleum reservoirs, fluid properties, laboratory experiments, and production methods. Major references and resources are also provided.
This document provides an overview of a reservoir engineering course focused on fundamental rock properties. It discusses key topics like porosity, saturation, wettability, capillary pressure, and how they are determined through laboratory core analysis. Porosity refers to the pore space available to hold fluids and is classified as absolute or effective porosity. Saturation represents the fraction of pore space occupied by a fluid. Capillary pressure describes the pressure differential between immiscible fluids based on interface curvature. Laboratory tests on core samples are used to characterize these important rock properties.
This document provides an overview of methods for calculating natural gas properties including:
1. Empirical correlations for calculating gas compressibility factors such as Hall-Yarborough, Dranchuk-Abu-Kassem, and Dranchuk-Purvis-Robinson.
2. Calculation of gas formation volume factor and gas expansion factor from gas compressibility factors and properties.
3. Empirical correlations for calculating gas viscosity including Carr-Kobayashi-Burrows and Lee-Gonzalez-Eakin.
This document provides an overview of methods for calculating properties of reservoir fluids including gas and crude oil. It discusses empirical correlations for calculating z-factors, gas properties like compressibility and viscosity, and crude oil properties like density, solubility of dissolved gas, and bubble point pressure. The key empirical correlations presented for estimating gas solubility (Rs) and methods for determining bubble point pressure are Standing, Vasquez-Beggs, Glaso, Marhoun, Petrosky-Farshad, and correlations based on experimental PVT data.
This document provides an overview of reservoir fluid properties including:
1. Crude oil properties such as density, gas solubility, bubble point pressure, formation volume factor, compressibility, and correlations to calculate these properties.
2. Water properties including water formation volume factor, viscosity, gas solubility in water, and water isothermal compressibility.
3. The total formation volume factor and viscosity of crude oil are also discussed along with definitions of dead-oil, saturated-oil, and undersaturated oil viscosities.
The document discusses procedures and results from differential liberation experiments used to characterize reservoir fluids. Key points:
- Differential liberation experiments slowly depressurize a reservoir fluid sample to measure properties like oil and gas volumes, gas composition, and solution gas-oil ratio at different pressures.
- Properties measured include formation volumes factors (Bo and Bg) which indicate volume changes from reservoir to surface conditions, and solution gas-oil ratio (Rs) which provides ratio of gas to oil volumes.
- Trends in Bo, Bg and Rs with pressure provide insight into fluid behavior during production.
This document provides an overview of three primary reservoir fluid property experiments: constant-mass expansion (CME), constant-volume depletion (CVD), and differential liberation (DL). It describes the objectives, procedures, and key results of each experiment. The CME experiment measures formation volume factor, compressibility, and relative fluid volumes at varying pressures. The CVD simulates reservoir depletion, measuring properties like liquid dropout and gas compositions. The DL characterizes differential gas liberation from oil during pressure decline.
This document provides an overview of methods for calculating reservoir fluid properties, including crude oil and water properties. It discusses calculating the total formation volume factor (Bt) using correlations like Standing's and Glaso's. It also covers calculating crude oil viscosity, including dead-oil viscosity using Beal's correlation, saturated oil viscosity using Chew-Connally, and undersaturated oil viscosity using Vasquez-Beggs. The document provides equations and discusses experimental data ranges for various fluid property correlations.
This document covers reservoir engineering concepts related to petroleum reservoirs. It discusses the classification of oil and gas reservoirs based on phase behavior and pressure-temperature relationships. It also summarizes key reservoir fluid properties for both gas and crude oil, including compressibility factors, density, molecular weight, and formation volume factors. The behaviors of real gases are contrasted with ideal gases and methods for determining compressibility factors are presented.
This document outlines the syllabus for a Reservoir Engineering 1 course. The 3 credit hour course is intended for sophomore and junior petroleum engineering students and covers fundamental reservoir engineering concepts and their practical applications. Lectures will be divided into two 50-slide presentations with a short break. Students will be assessed based on class activities, a midterm exam, and a final exam. The course schedule lists 16 lectures covering topics like petroleum reservoirs, fluid properties, laboratory experiments, and production methods. Major references and resources are also provided.
This document provides an overview of a reservoir engineering course focused on fundamental rock properties. It discusses key topics like porosity, saturation, wettability, capillary pressure, and how they are determined through laboratory core analysis. Porosity refers to the pore space available to hold fluids and is classified as absolute or effective porosity. Saturation represents the fraction of pore space occupied by a fluid. Capillary pressure describes the pressure differential between immiscible fluids based on interface curvature. Laboratory tests on core samples are used to characterize these important rock properties.
Petroleum Zones - Models and Simulations of Prototypes (Oil and Gas Industry)
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