This document discusses dynamic routing protocols and routing tables. It covers the evolution of dynamic routing protocols, their components, and classification. Dynamic routing protocols are used to automatically discover remote networks and maintain up-to-date routing information. The routing table contains different types of entries, such as directly connected interfaces, static routes, and dynamically learned routes. Dynamic routing protocols help routers learn optimal paths to destinations and update their routing tables accordingly.
This document discusses spanning tree protocols. It begins by explaining the purpose of STP in preventing layer 2 loops. It then covers different STP varieties like PVST+ and Rapid PVST+, and how they operate independently on each VLAN. The document ends by providing instructions on configuring PVST+ and Rapid PVST+, including setting the root bridge, enabling features like PortFast and BPDU Guard, and troubleshooting the STP topology.
This document provides instructor materials for a chapter on static routing. The chapter objectives are to explain static routing concepts, configure static and default routes, and troubleshoot static route issues. Static routes are manually configured without a routing protocol. They provide security, use fewer resources than dynamic routing, and are useful for small networks or stub networks with a single connection. The document covers configuring standard static routes, default routes, summary routes, and floating routes in IPv4 and IPv6 along with verifying the configurations. Troubleshooting tips include using ping, traceroute, and checking the routing table.
The document provides instructional materials for a chapter on the network layer. It covers topics like network layer protocols including IPv4 and IPv6, routing, routers, and configuring Cisco routers. Sections explain how network layer protocols support communication across networks and the purpose of fields in IPv4 and IPv6 packets. It also details how hosts, routers, and their routing tables determine the path for packets to travel to reach their destination on either the local network or remote networks.
This document discusses spanning tree protocols. It begins by explaining the purpose of STP in preventing layer 2 loops. It then covers different STP varieties like PVST+ and Rapid PVST+, and how they operate independently on each VLAN. The document ends by providing instructions on configuring PVST+ and Rapid PVST+, including setting the root bridge, enabling features like PortFast and BPDU Guard, and troubleshooting the STP topology.
This document provides instructor materials for a chapter on static routing. The chapter objectives are to explain static routing concepts, configure static and default routes, and troubleshoot static route issues. Static routes are manually configured without a routing protocol. They provide security, use fewer resources than dynamic routing, and are useful for small networks or stub networks with a single connection. The document covers configuring standard static routes, default routes, summary routes, and floating routes in IPv4 and IPv6 along with verifying the configurations. Troubleshooting tips include using ping, traceroute, and checking the routing table.
The document provides instructional materials for a chapter on the network layer. It covers topics like network layer protocols including IPv4 and IPv6, routing, routers, and configuring Cisco routers. Sections explain how network layer protocols support communication across networks and the purpose of fields in IPv4 and IPv6 packets. It also details how hosts, routers, and their routing tables determine the path for packets to travel to reach their destination on either the local network or remote networks.
CCNA (R & S) Module 02 - Connecting Networks - Chapter 2
Point to Point Connections, Serial Communications, Troubleshoot WAN Connectivity, PPP Sessions
OSPF is a link-state routing protocol that can operate in single-area or multi-area mode. This document discusses single-area OSPF, including enabling OSPFv2 and OSPFv3, configuring interfaces, and verifying neighbor relationships and routing tables. Key aspects of single-area OSPF include using the network command to enable OSPF on interfaces, electing a designated router, and commands for viewing routing information and neighbor status.
CCNA (R & S) Module 01 - Introduction to Networks - Chapter 4Waqas Ahmed Nawaz
This document is from a Cisco networking textbook. It covers network access and includes sections on physical layer protocols, network media, data link layer protocols, and media access control. The physical layer accepts frames from the data link layer and encodes them for transmission on different media types. Common network cabling includes copper-based options like UTP and coaxial, as well as fiber-optic cabling. Wireless media also allows for radio-based networking. The data link layer prepares frames for transmission and defines media access. Different methods like CSMA/CD are used depending on the topology and media.
This document discusses dynamic routing protocols and how they operate. It covers distance vector protocols like RIP that exchange periodic updates between neighbors to maintain routing tables. It also covers link-state protocols like OSPF that build a complete network map by flooding link-state updates and running the Dijkstra algorithm to calculate the shortest path to all destinations. Distance vector protocols scale better, while link-state protocols converge faster but require more resources to run the SPF algorithm and store link-state databases. The chapter compares the key features and operation of distance vector and link-state routing protocols.
This document discusses device discovery, management, and maintenance. It covers using protocols like CDP and LLDP for network discovery. Device management topics include configuring NTP and syslog, while device maintenance includes backing up configurations, restoring files, and upgrading software and licenses.
The document discusses EIGRP (Enhanced Interior Gateway Routing Protocol) and how to implement it for IPv4 and IPv6 routing. It covers the key characteristics and features of EIGRP, including how it uses the Diffusing Update Algorithm (DUAL) to calculate paths and establish neighbor adjacencies. It also provides instructions on configuring EIGRP for IPv4 and IPv6 on Cisco routers, and describes commands to verify proper operation and troubleshoot issues.
This document discusses tuning and troubleshooting OSPF routing. Section 10.1 covers advanced single-area OSPF configurations, including configuring the designated router, propagating default routes, and fine-tuning OSPF interfaces. Section 10.2 discusses components of troubleshooting single-area OSPF, including verifying neighbor states and routing tables, and provides examples of troubleshooting neighbor and routing issues for OSPFv2 and OSPFv3. The chapter summary recaps key points about OSPF network types, the designated router, default route propagation, and multi-area OSPF troubleshooting.
EtherChannel and HSRP are protocols for link aggregation and first hop redundancy. EtherChannel aggregates multiple switch links into a single logical trunk to increase bandwidth. It uses PAgP or LACP for negotiation. HSRP provides default gateway redundancy on a LAN by sharing a virtual IP address between routers. The router with the highest priority becomes the active default gateway with the standby ready to take over if needed.
This document discusses dynamic routing protocols and contains sections on dynamic routing protocols, RIPv2 configuration, routing tables, and a summary. Some key points include:
- Dynamic routing protocols allow routers to automatically learn about remote networks and maintain up-to-date routing information to choose the best path.
- RIPv2 is configured on routers to exchange routing information with neighboring routers using various routing protocol messages and algorithms.
- Routing tables contain entries for directly connected networks, remote networks learned dynamically, and default routes. IPv4 tables can include ultimate, level 1, and level 2 routes while IPv6 tables contain only ultimate routes.
- The routing lookup process uses administrative distances and longest prefix matching to determine the best route
1) Explain the basic operation of dynamic routing protocols.
2) Compare and contrast dynamic and static routing.
3) Determine which networks are available during an initial network discovery phase.
4) Define the different categories of routing protocols.
5) Describe the process by which distance vector routing protocols learn about other networks.
6) Identify the types of distance-vector routing protocols.
7) Configure the RIP routing protocol.
8) Configure the RIPng routing protocol.
9) Explain the process by which link-state routing protocols learn about other networks.
10) Describe the information sent in a link-state update.
11) Describe advantages and disadvantages of using link-state routing protocols.
12) Identify protocols that use the link-state routing process. (OSPF, IS-IS)
13) Determine the route source, administrative distance, and metric for a given route.
14) Explain the concept of a parent/child relationship in a dynamically built routing table.
15) Compare the IPv4 classless route lookup process and the IPv6 lookup process.
16) Analyze a routing table to determine which route will be used to forward a packet.
CCNA (R & S) Module 02 - Connecting Networks - Chapter 2
Point to Point Connections, Serial Communications, Troubleshoot WAN Connectivity, PPP Sessions
OSPF is a link-state routing protocol that can operate in single-area or multi-area mode. This document discusses single-area OSPF, including enabling OSPFv2 and OSPFv3, configuring interfaces, and verifying neighbor relationships and routing tables. Key aspects of single-area OSPF include using the network command to enable OSPF on interfaces, electing a designated router, and commands for viewing routing information and neighbor status.
CCNA (R & S) Module 01 - Introduction to Networks - Chapter 4Waqas Ahmed Nawaz
This document is from a Cisco networking textbook. It covers network access and includes sections on physical layer protocols, network media, data link layer protocols, and media access control. The physical layer accepts frames from the data link layer and encodes them for transmission on different media types. Common network cabling includes copper-based options like UTP and coaxial, as well as fiber-optic cabling. Wireless media also allows for radio-based networking. The data link layer prepares frames for transmission and defines media access. Different methods like CSMA/CD are used depending on the topology and media.
This document discusses dynamic routing protocols and how they operate. It covers distance vector protocols like RIP that exchange periodic updates between neighbors to maintain routing tables. It also covers link-state protocols like OSPF that build a complete network map by flooding link-state updates and running the Dijkstra algorithm to calculate the shortest path to all destinations. Distance vector protocols scale better, while link-state protocols converge faster but require more resources to run the SPF algorithm and store link-state databases. The chapter compares the key features and operation of distance vector and link-state routing protocols.
This document discusses device discovery, management, and maintenance. It covers using protocols like CDP and LLDP for network discovery. Device management topics include configuring NTP and syslog, while device maintenance includes backing up configurations, restoring files, and upgrading software and licenses.
The document discusses EIGRP (Enhanced Interior Gateway Routing Protocol) and how to implement it for IPv4 and IPv6 routing. It covers the key characteristics and features of EIGRP, including how it uses the Diffusing Update Algorithm (DUAL) to calculate paths and establish neighbor adjacencies. It also provides instructions on configuring EIGRP for IPv4 and IPv6 on Cisco routers, and describes commands to verify proper operation and troubleshoot issues.
This document discusses tuning and troubleshooting OSPF routing. Section 10.1 covers advanced single-area OSPF configurations, including configuring the designated router, propagating default routes, and fine-tuning OSPF interfaces. Section 10.2 discusses components of troubleshooting single-area OSPF, including verifying neighbor states and routing tables, and provides examples of troubleshooting neighbor and routing issues for OSPFv2 and OSPFv3. The chapter summary recaps key points about OSPF network types, the designated router, default route propagation, and multi-area OSPF troubleshooting.
EtherChannel and HSRP are protocols for link aggregation and first hop redundancy. EtherChannel aggregates multiple switch links into a single logical trunk to increase bandwidth. It uses PAgP or LACP for negotiation. HSRP provides default gateway redundancy on a LAN by sharing a virtual IP address between routers. The router with the highest priority becomes the active default gateway with the standby ready to take over if needed.
This document discusses dynamic routing protocols and contains sections on dynamic routing protocols, RIPv2 configuration, routing tables, and a summary. Some key points include:
- Dynamic routing protocols allow routers to automatically learn about remote networks and maintain up-to-date routing information to choose the best path.
- RIPv2 is configured on routers to exchange routing information with neighboring routers using various routing protocol messages and algorithms.
- Routing tables contain entries for directly connected networks, remote networks learned dynamically, and default routes. IPv4 tables can include ultimate, level 1, and level 2 routes while IPv6 tables contain only ultimate routes.
- The routing lookup process uses administrative distances and longest prefix matching to determine the best route
1) Explain the basic operation of dynamic routing protocols.
2) Compare and contrast dynamic and static routing.
3) Determine which networks are available during an initial network discovery phase.
4) Define the different categories of routing protocols.
5) Describe the process by which distance vector routing protocols learn about other networks.
6) Identify the types of distance-vector routing protocols.
7) Configure the RIP routing protocol.
8) Configure the RIPng routing protocol.
9) Explain the process by which link-state routing protocols learn about other networks.
10) Describe the information sent in a link-state update.
11) Describe advantages and disadvantages of using link-state routing protocols.
12) Identify protocols that use the link-state routing process. (OSPF, IS-IS)
13) Determine the route source, administrative distance, and metric for a given route.
14) Explain the concept of a parent/child relationship in a dynamically built routing table.
15) Compare the IPv4 classless route lookup process and the IPv6 lookup process.
16) Analyze a routing table to determine which route will be used to forward a packet.
Chapter 7: Objectives
--------------------------------------------
Explain the basic operation of dynamic routing protocols.
Compare and contrast dynamic and static routing.
Determine which networks are available during an initial network discovery phase.
Define the different categories of routing protocols.
Describe the process by which distance vector routing protocols learn about other networks.
Identify the types of distance-vector routing protocols.
Configure the RIP routing protocol.
Configure the RIPng routing protocol.
Explain the process by which link-state routing protocols learn about other networks.
Describe the information sent in a link-state update.
Describe advantages and disadvantages of using link-state routing protocols.
Identify protocols that use the link-state routing process. (OSPF, IS-IS)
Determine the route source, administrative distance, and metric for a given route.
Explain the concept of a parent/child relationship in a dynamically built routing table.
Compare the IPv4 classless route lookup process and the IPv6 lookup process.
Analyze a routing table to determine which route will be used to forward a packet.
Yaser Rahmati | یاسر رحمتی
Rahmati Academy | آکادمی رحمتی
www.yaser-rahmati.ir
www.rahmati-academy.ir
This document provides an overview of dynamic routing protocols. It discusses the basic operation and purpose of dynamic routing protocols, including how they discover networks, exchange routing information, and converge on a network view. It also categorizes routing protocols as either distance vector or link-state, and covers example protocols like RIP, EIGRP, and OSPF. Specific topics covered include dynamic routing fundamentals, static versus dynamic routing, protocol metrics, and the operation of distance vector routing.
CCNA 2 Routing and Switching v5.0 Chapter 7Nil Menon
This document discusses dynamic routing protocols and provides an overview of how they operate. It explains that dynamic routing protocols automatically share information about remote networks to determine the best path. The document compares static and dynamic routing, and outlines the basic process by which routers using dynamic routing protocols like RIP discover networks, exchange routing information, and update their routing tables. Objectives of the chapter are also listed, such as explaining dynamic routing operation and configuring RIP and OSPF protocols.
The document discusses distance vector routing protocols. It describes the characteristics of distance vector protocols, including that they use periodic updates where routers broadcast their full routing tables to neighbors. The document outlines the network discovery process, how routing tables are maintained through timers and triggered updates, and how issues like routing loops can occur if protocols are improperly configured. Mechanisms to prevent routing loops such as split horizon and poison reverse are also covered.
The document discusses routing protocols and their use in small-to-medium networks and between autonomous systems on the internet. It describes how routers use routing tables to determine the best paths, and how routes can be either static or dynamic via routing protocols. Key routing protocols discussed include RIP, EIGRP, OSPF, and BGP, as well as the differences between interior gateway protocols used within autonomous systems and exterior gateway protocols used between systems. The document provides guidance on selecting and implementing appropriate routing protocols for different network needs and sizes.
Dynamic routing protocols share routing information between routers to automatically update routing tables when network changes occur and determine the best path. They are classified as interior gateway protocols, which route within an autonomous system, or exterior gateway protocols, which route between autonomous systems. Metrics like bandwidth and hop count are used to calculate the best path, while administrative distance indicates the priority of routes.
This document covers configuration of static routing in Cisco routers. It discusses the advantages and disadvantages of static routing compared to dynamic routing. It provides instructions on how to configure various types of static routes in IPv4 and IPv6 including next-hop, default, summary, and floating static routes. Troubleshooting steps for static route issues are also presented.
Chapter 6: Objectives
-----------------------------------------------
Explain the advantages and disadvantages of static routing.
Explain the purpose of different types of static routes.
Configure IPv4 and IPv6 static routes by specifying a next-hop address.
Configure an IPv4 and IPv6 default routes.
Explain the use of legacy classful addressing in network implementation.
Explain the purpose of CIDR in replacing classful addressing.
Design and implement a hierarchical addressing scheme.
Configure an IPv4 and IPv6 summary network address to reduce the number of routing table updates.
Configure a floating static route to provide a backup connection.
Explain how a router processes packets when a static route is configured.
Troubleshoot common static and default route configuration issues.
Yaser Rahmati | یاسر رحمتی
Rahmati Academy | آکادمی رحمتی
www.yaser-rahmati.ir
www.rahmati-academy.ir
This document discusses static routing concepts and configuration. It covers implementing static and default routes for IPv4 and IPv6, as well as summarization, floating static routes, and troubleshooting. The objectives are to explain static routing advantages/disadvantages, configure different static route types, implement CIDR and VLSM, and troubleshoot common issues. Configuration examples are provided for various static route scenarios.
CCNA 2 Routing and Switching v5.0 Chapter 6Nil Menon
This document discusses static routing and how to configure static routes on Cisco routers. It begins with an overview of static routing, including the advantages and disadvantages. It then covers different types of static routes such as standard, default, summary, and floating static routes. The document provides examples of how to configure IPv4 and IPv6 static routes, default routes, and verify the routes. It also includes background information on topics like classful addressing and CIDR that are relevant to static route configuration.
The document discusses the network layer in the OSI model. It describes the key responsibilities of the network layer, including addressing, routing data between end devices, and allowing communication between different networks. The most common network layer protocol is the Internet Protocol (IP), which uses addresses and best-effort delivery to route packets to their destinations. IP packets contain source and destination addresses, and may be routed through multiple networks using hierarchical addressing schemes, routers, and routing tables maintained by routing protocols. Network testing tools like ping and traceroute allow engineers to diagnose connectivity issues.
This document discusses dynamic routing protocols and concepts. It describes the functions of dynamic routing protocols as dynamically sharing information between routers, automatically updating routing tables when network topologies change, and determining the best path to destinations. It classifies routing protocols as either interior gateway protocols, used within autonomous systems, or exterior gateway protocols, used between autonomous systems. It also covers routing metrics, administrative distance, and the components of a routing table.
The document discusses distance vector routing protocols. It describes how distance vector protocols work by maintaining routing tables using periodic updates that contain the entire routing table. It also discusses the network discovery process, how routing loops can occur, and mechanisms like split horizon that are used to prevent routing loops. Examples of distance vector protocols discussed are RIP and EIGRP.
This document provides an overview of dynamic routing protocols and configuration of RIPv2. It discusses the purpose of dynamic routing protocols in discovering remote networks, maintaining up-to-date routing information, and choosing the best path. RIPv2 configuration topics include enabling RIP, advertising networks, verifying RIP operation, and propagating a default route. The document also examines the components of routing table entries, such as route source, metric, and next hop. It describes the hierarchy of dynamically learned routes including ultimate, level 1, parent and child routes.
This document provides an overview of routing fundamentals and subnets. It defines key concepts like routed protocols, routing protocols, IP addressing, and subnetting. Routed protocols like IP define packet formats and addressing to enable communication across networks, while routing protocols like RIP exchange information to maintain routing tables and select optimal paths. The document also explains how routers use routing tables to determine the best path for sending packets and contains examples of subnetting IP addresses to create multiple subnets within a class C network.
The document discusses distance vector routing protocols. It describes their key characteristics like periodic updates and inclusion of the full routing table in updates. It explains the network discovery process where directly connected networks are learned first, and convergence is reached when all routers have consistent routing information. The document also covers routing table maintenance methods, potential issues like routing loops, and techniques used to prevent loops.
Similar to CCNA (R & S) Module 03 - Routing & Switching Essentials - Chapter 3 (20)
This document discusses multiarea OSPF routing. It explains that multiarea OSPF divides a large network into multiple areas to reduce routing table sizes and the frequency of SPF calculations. Areas are connected via Area Border Routers (ABRs) and the backbone area. The document covers OSPF router types, how different LSA types are used to distribute routing information between areas, and how to configure and verify a multiarea OSPF implementation.
This document discusses tuning and troubleshooting EIGRP routing. Section 7.1 covers tuning EIGRP, including configuring automatic summarization, propagating default routes, and fine-tuning EIGRP interfaces. Section 7.2 covers troubleshooting EIGRP, such as addressing neighbor and routing table issues. The chapter summary emphasizes that modifying EIGRP features and troubleshooting problems is an essential skill for network engineers managing large enterprise networks using EIGRP. It provides an overview of key tuning and troubleshooting tasks covered in the document.
This document discusses designing and scaling campus wired LANs. It covers hierarchical network designs with access, distribution and core layers. Selecting the proper network devices is important, including switches with sufficient port density, forwarding rates and wire speeds. Switches and routers require configuration, management and troubleshooting using commands like show ip route, show interfaces and show mac-address-table. Designing networks with redundancy, smaller failure domains and link aggregation allows networks to scale effectively.
This document provides instructor materials for a chapter on static routing. The chapter objectives are to explain static routing concepts, configure static and default routes, and troubleshoot static route issues. Static routes are manually configured without a routing protocol. They can be used for small networks, stub networks with a single connection, and default routes. The document shows how to configure static routes, default routes, floating static routes, and static host routes in IPv4 and IPv6 on Cisco routers. It also discusses troubleshooting missing routes and connectivity problems.
This presentation was provided by Steph Pollock of The American Psychological Association’s Journals Program, and Damita Snow, of The American Society of Civil Engineers (ASCE), for the initial session of NISO's 2024 Training Series "DEIA in the Scholarly Landscape." Session One: 'Setting Expectations: a DEIA Primer,' was held June 6, 2024.
LAND USE LAND COVER AND NDVI OF MIRZAPUR DISTRICT, UPRAHUL
This Dissertation explores the particular circumstances of Mirzapur, a region located in the
core of India. Mirzapur, with its varied terrains and abundant biodiversity, offers an optimal
environment for investigating the changes in vegetation cover dynamics. Our study utilizes
advanced technologies such as GIS (Geographic Information Systems) and Remote sensing to
analyze the transformations that have taken place over the course of a decade.
The complex relationship between human activities and the environment has been the focus
of extensive research and worry. As the global community grapples with swift urbanization,
population expansion, and economic progress, the effects on natural ecosystems are becoming
more evident. A crucial element of this impact is the alteration of vegetation cover, which plays a
significant role in maintaining the ecological equilibrium of our planet.Land serves as the foundation for all human activities and provides the necessary materials for
these activities. As the most crucial natural resource, its utilization by humans results in different
'Land uses,' which are determined by both human activities and the physical characteristics of the
land.
The utilization of land is impacted by human needs and environmental factors. In countries
like India, rapid population growth and the emphasis on extensive resource exploitation can lead
to significant land degradation, adversely affecting the region's land cover.
Therefore, human intervention has significantly influenced land use patterns over many
centuries, evolving its structure over time and space. In the present era, these changes have
accelerated due to factors such as agriculture and urbanization. Information regarding land use and
cover is essential for various planning and management tasks related to the Earth's surface,
providing crucial environmental data for scientific, resource management, policy purposes, and
diverse human activities.
Accurate understanding of land use and cover is imperative for the development planning
of any area. Consequently, a wide range of professionals, including earth system scientists, land
and water managers, and urban planners, are interested in obtaining data on land use and cover
changes, conversion trends, and other related patterns. The spatial dimensions of land use and
cover support policymakers and scientists in making well-informed decisions, as alterations in
these patterns indicate shifts in economic and social conditions. Monitoring such changes with the
help of Advanced technologies like Remote Sensing and Geographic Information Systems is
crucial for coordinated efforts across different administrative levels. Advanced technologies like
Remote Sensing and Geographic Information Systems
9
Changes in vegetation cover refer to variations in the distribution, composition, and overall
structure of plant communities across different temporal and spatial scales. These changes can
occur natural.
ISO/IEC 27001, ISO/IEC 42001, and GDPR: Best Practices for Implementation and...PECB
Denis is a dynamic and results-driven Chief Information Officer (CIO) with a distinguished career spanning information systems analysis and technical project management. With a proven track record of spearheading the design and delivery of cutting-edge Information Management solutions, he has consistently elevated business operations, streamlined reporting functions, and maximized process efficiency.
Certified as an ISO/IEC 27001: Information Security Management Systems (ISMS) Lead Implementer, Data Protection Officer, and Cyber Risks Analyst, Denis brings a heightened focus on data security, privacy, and cyber resilience to every endeavor.
His expertise extends across a diverse spectrum of reporting, database, and web development applications, underpinned by an exceptional grasp of data storage and virtualization technologies. His proficiency in application testing, database administration, and data cleansing ensures seamless execution of complex projects.
What sets Denis apart is his comprehensive understanding of Business and Systems Analysis technologies, honed through involvement in all phases of the Software Development Lifecycle (SDLC). From meticulous requirements gathering to precise analysis, innovative design, rigorous development, thorough testing, and successful implementation, he has consistently delivered exceptional results.
Throughout his career, he has taken on multifaceted roles, from leading technical project management teams to owning solutions that drive operational excellence. His conscientious and proactive approach is unwavering, whether he is working independently or collaboratively within a team. His ability to connect with colleagues on a personal level underscores his commitment to fostering a harmonious and productive workplace environment.
Date: May 29, 2024
Tags: Information Security, ISO/IEC 27001, ISO/IEC 42001, Artificial Intelligence, GDPR
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Strategies for Effective Upskilling is a presentation by Chinwendu Peace in a Your Skill Boost Masterclass organisation by the Excellence Foundation for South Sudan on 08th and 09th June 2024 from 1 PM to 3 PM on each day.
A review of the growth of the Israel Genealogy Research Association Database Collection for the last 12 months. Our collection is now passed the 3 million mark and still growing. See which archives have contributed the most. See the different types of records we have, and which years have had records added. You can also see what we have for the future.
Walmart Business+ and Spark Good for Nonprofits.pdfTechSoup
"Learn about all the ways Walmart supports nonprofit organizations.
You will hear from Liz Willett, the Head of Nonprofits, and hear about what Walmart is doing to help nonprofits, including Walmart Business and Spark Good. Walmart Business+ is a new offer for nonprofits that offers discounts and also streamlines nonprofits order and expense tracking, saving time and money.
The webinar may also give some examples on how nonprofits can best leverage Walmart Business+.
The event will cover the following::
Walmart Business + (https://business.walmart.com/plus) is a new shopping experience for nonprofits, schools, and local business customers that connects an exclusive online shopping experience to stores. Benefits include free delivery and shipping, a 'Spend Analytics” feature, special discounts, deals and tax-exempt shopping.
Special TechSoup offer for a free 180 days membership, and up to $150 in discounts on eligible orders.
Spark Good (walmart.com/sparkgood) is a charitable platform that enables nonprofits to receive donations directly from customers and associates.
Answers about how you can do more with Walmart!"
Main Java[All of the Base Concepts}.docxadhitya5119
This is part 1 of my Java Learning Journey. This Contains Custom methods, classes, constructors, packages, multithreading , try- catch block, finally block and more.