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Juniper - Switches, Routers & Firewalls | Models List
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New Juniper RE-S-1800X4
The Routing Engine runs the Junosos Software processes that run on the Routing Engine maintain the routing tables, manage the routing protocols used on the router, control the router interfaces, control some chassis components, and provide the interface for system management and user access to the router. Application/Usage: Data Networking Product Type: Routing Engine Interfaces/Ports Details: 1 x 10/100Base-TX Interfaces/Ports Details: 1 Product Type: Routing Engine Compatibility: Juniper Networks Mx Series 3D Universal Edge Routers Manufacturer Part Number: RE-S-1800X4-16G-R Interfaces/Ports Details: 1 x USB Interfaces/Ports Details: 1 x RJ-45 10/100Base-TX Network Auto-sensing Management Interfaces/Ports Details: 1 x RJ-45 Console Management Interfaces/Ports Details: 1 x RJ-45 Auxiliary Management Weight (Approximate): 2.40 lb Form Factor: Hot-swappable Manufacturer: Juniper Networks, Inc Product Model: RE-S-1800X4-16G-R Product Name: RE-S-1800X4-16G-R Routing Engine Brand Name: Juniper Brand Name: Juniper Height: 1.3 Width: 11 Depth: 7.8 Number of Total Expansion Slots: 1
Product information
Package Dimensions11 x 8 x 1 inches
Item Weight2.2 pounds
Shipping Weight2 pounds
Manufacturer JUNIPER NETWORKING
Item model numberRE-S-1800X4-16G
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Network Device Router
A router is a networking device that forwards data packets between computer networks. Routers perform the traffic directing functions on the Internet. Data sent through the internet, such as a web page or email, is in the form of data packets. A packet is typically forwarded from one router to another router through the networks that constitute an internetwork until it reaches its destination node.
A router is connected to two or more data lines from different networks. When a data packet comes in on one of the lines, the router reads the network address information in the packet to determine the ultimate destination. Then, using information in its routing table or routing policy, it directs the packet to the next network on its journey.
The most familiar type of routers are home and small office routers that simply forward IP packets between the home computers and the Internet. An example of a router would be the owner’s cable or DSL router, which connects to the Internet through an Internet service provider (ISP). More sophisticated routers, such as enterprise routers, connect large business or ISP networks up to the powerful core routers that forward data at high speed along the optical fiber lines of the Internet backbone. Though routers are typically dedicated hardware devices, software-based routers also exist.
Operation
When multiple routers are used in interconnected networks, the routers can exchange information about destination addresses using a routing protocol. Each router builds up a routing table listing the preferred routes between any two systems on the interconnected networks.
A router has two types of network element components organized onto separate planes:
1.Control plane: A router maintains a routing table that lists which route should be used to forward a data packet, and through which physical interface connection. It does this using internal preconfigured directives, called static routes, or by learning routes dynamically using a routing protocol. Static and dynamic routes are stored in the routing table. The control-plane logic then strips non-essential directives from the table and builds a forwarding information base (FIB) to be used by the forwarding plane.
2.Forwarding plane: The router forwards data packets between incoming and outgoing interface connections. It forwards them to the correct network type using information that the packet header contains matched to entries in the FIB supplied by the control plane.
Applications
A router may have interfaces for different types of physical layer connections, such as copper cables, fiber optic, or wireless transmission. It can also support different network layer transmission standards. Each network interface is used to enable data packets to be forwarded from one transmission system to another. Routers may also be used to connect two or more logical groups of computer devices known as subnets, each with a different network prefix.
Routers may provide connectivity within enterprises, between enterprises and the Internet, or between internet service providers’ (ISPs’) networks. The largest routers (such as the Cisco CRS-1 or Juniper PTX) interconnect the various ISPs, or may be used in large enterprise networks. Smaller routers usually provide connectivity for typical home and office networks.
All sizes of routers may be found inside enterprises. The most powerful routers are usually found in ISPs, academic and research facilities. Large businesses may also need more powerful routers to cope with ever-increasing demands of intranetdata traffic. A hierarchical internetworking model for interconnecting routers in large networks is in common use.
Access, core and distribution
Access routers, including small office/home office (SOHO) models, are located at home and customer sites such as branch offices that do not need hierarchical routing of their own. Typically, they are optimized for low cost. Some SOHO routers are capable of running alternative free Linux-based firmware like Tomato, OpenWrt or DD-WRT.
Distribution routers aggregate traffic from multiple access routers. Distribution routers are often responsible for enforcing quality of service across a wide area network (WAN), so they may have considerable memory installed, multiple WAN interface connections, and substantial onboard data processing routines. They may also provide connectivity to groups of file servers or other external networks.
In enterprises, a core router may provide a collapsed backbone interconnecting the distribution tier routers from multiple buildings of a campus, or large enterprise locations. They tend to be optimized for high bandwidth, but lack some of the features of edge routers.
Security
External networks must be carefully considered as part of the overall security strategy of the local network. A router may include a firewall, VPN handling, and other security functions, or these may be handled by separate devices. Many companies produced security-oriented routers, including Cisco PIX series, Cisco Meraki MX series and Juniper NetScreen. Routers also commonly perform network address translation (which allows multiple devices on a network to share a single public IP address) and stateful packet inspection. Some experts argue that open source routers are more secure and reliable than closed source routers because open source routers allow mistakes to be quickly found and corrected.
Internet connectivity and internal use
Routers intended for ISP and major enterprise connectivity usually exchange routing information using the Border Gateway Protocol (BGP). RFC 4098 standard defines the types of BGP routers according to their functions:
Edge router: Also called a provider edge router, is placed at the edge of an ISP network. The router uses External BGP to EBGP routers in other ISPs, or a large enterprise Autonomous System.
Subscriber edge router: Also called a Customer Edge router, is located at the edge of the subscriber’s network, it also uses EBGP to its provider’s Autonomous System. It is typically used in an (enterprise) organization.
Inter-provider border router: Interconnecting ISPs, is a BGP router that maintains BGP sessions with other BGP routers in ISP Autonomous Systems.
Core router: A core router resides within an Autonomous System as a back bone to carry traffic between edge routers.
Within an ISP: In the ISP’s Autonomous System, a router uses internal BGP to communicate with other ISP edge routers, other intranet core routers, or the ISP’s intranet provider border routers.
“Internet backbone:” The Internet no longer has a clearly identifiable backbone, unlike its predecessor networks. See default-free zone (DFZ). The major ISPs’ system routers make up what could be considered to be the current Internet backbone core. ISPs operate all four types of the BGP routers described here. An ISP “core” router is used to interconnect its edge and border routers. Core routers may also have specialized functions in virtual private networks based on a combination of BGP and Multi-Protocol Label Switching protocols.
Port forwarding: Routers are also used for port forwarding between private Internet-connected servers.
Voice/Data/Fax/Video Processing Routers: Commonly referred to as access servers or gateways, these devices are used to route and process voice, data, video and fax traffic on the Internet. Since 2005, most long-distance phone calls have been processed as IP traffic (VOIP) through a voice gateway. Use of access server type routers expanded with the advent of the Internet, first with dial-up access and another resurgence with voice phone service.
Larger networks commonly use multilayer switches, with layer 3 devices being used to simply interconnect multiple subnets within the same security zone, and higher layer switches when filtering, translation, load balancing or other higher level functions are required, especially between zones.
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Difference between router and switch
Difference between router and switch, an exceptionally prevalent and imperative inquiry which is regularly asked by many individuals.
In order to know each and everything about the difference between router and switch, the underneath article is composed in a particular request in which you are initially presented with both the gadgets independently.
What is a router?
What is a networking switch?
What's more, from that point forward, an all-around oversaw and sorted out table is given demonstrating the primary focuses sufficiently giving insights about the distinction amongst switch and switch.
Before knowing the distinction amongst switch and switch, it is vital for us to think about them independently i.e. what are they, how they work and of which parts they are made of.
What is a router?
A router might be said as a systems administration gadget which interfaces distinctive PC systems, for instance, on the off chance that we need to associate a home system with the Internet. Switches are the workhorses which exchange parcels of data between systems to determine related support correspondence between two bounces in an internetwork. Switches work at Layer three (arrange layer) of the OSI display, a switch utilizes the goal IP Address in an information parcel to figure out where to additionally convey the bundle.
What is a networking switch?
A system switch is a gadget which is utilized to interface diverse gadgets together on a solitary PC arrange. A switch is otherwise called an exchanging center point, crossing over center, or a MAC connect. Switches fundamentally utilize the MAC delivers to forward the information to the coveted goal. A system switch is viewed as a Layer two gadget, working at the information connect layer; switches utilize bundle changing to get, process and forward the information.
Since we have now come to think about a switch and a system switch independently. Along these lines, we would now be able to take in the distinction between a switch and switch effectively.
A straightforward correlation graph demonstrating the contrast amongst switch and switch is given underneath:
Router
Switch
Function
It coordinates information in a system. It passes the information between home PCs, amongst PCs and the modem.
It permits to interface various gadgets and ports can be overseen, VLAN can make security additionally can apply.
Layer
Network Layer (Layer 3 devices)
It goes under Data Link Layer (Layer 2 of the OSI model).
Ports
2/4/8
A switch is a multi-port Bridge. 24/48 ports
Data Transmission form
Packet
Frame (L2 Switch) Frame & Packet (L3 switch)
Transmission Type
At Initial Level Broadcast then Uni-cast & Multicast
First broadcast; then unicast & multicast as needed.
Used in (LAN, WAN, MAN, PAN)
LAN, WAN
LAN
Device Type
Networking device
Active Device (With Software) & Networking device
Table
It stores IP address in the Routing table and maintains address at its own.
Switches use Content Accessible Memory (CAM) table that is typically accessed by ASIC (Application Specific integrated chips).
Transmission Mode
Full duplex
Half/Full duplex
Broadcast Domain
In Router, every port has its own Broadcast domain.
Switch has one broadcast domain [unless VLAN implemented]
Definition
A router is a networking device which connects a local network to the other local networks. At the Distribution Layer of the network, routers direct traffic and perform other functions critical to efficient network operation.
A network switch is a computer networking device which is used to connect several devices together on a computer network. A switch is considered as more advanced than a hub because a switch will send a message to the device that needs or request it.
Speed
1-10 Mbps (Wireless); 100 Mbps (Wired)
10/100 Mbps, 1 Gbps
Address used for data transmission
Uses IP address
Uses MAC address
Used to
Connect two or more networks
Connect two or more nodes in the same network or different network.
Device category
Intelligent Device
Intelligent Device
Bandwidth Sharing
Bandwidth sharing is dynamic. It enables either static or dynamic bandwidth sharing for modular cable interfaces. The default percent-value is 0. The percent-value lies in between 1-96.
There is no sharing in network switches. Port can be either 10, 100, 1000 or 10000 Mbps, individual.
Routing Decision
Takes faster routing decisions
Takes comparatively more time for complicated routing decisions
NAT (Network Address Translation)
Routers can perform NAT
Switches cannot perform NAT
Faster
In a different network environment (MAN/ WAN), a router is faster than an L3 switch.
In a LAN environment, an L3 switch is faster than a router (built in switching hardware)
Features
Firewall VPN Dynamic handling of Bandwidth
Priority range On/Off setting of port VLAN Port mirroring
Examples
Linksys WRT54GL Juniper MX & EX series Cisco 3900, 2900, 1900
Alcatel's OmniSwitch 9000; Cisco Catalyst switch 4500 and 6500 (10 Gbps)
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