Network+ Chapter 1 Test pt.1

Description

My test from chapter 1 notes
Tiffany Andrews
Quiz by Tiffany Andrews, updated more than 1 year ago
Tiffany Andrews
Created by Tiffany Andrews over 5 years ago
262
0

Resource summary

Question 1

Question
-- topologies are the easiest to troubleshoot and can easily scale to large sizes.
Answer
  • Star
  • Mesh
  • Hybrid

Question 2

Question
IP is a [blank_start]Network[blank_end] layer protocol
Answer
  • Network
  • Data-Link
  • Physical

Question 3

Question
Internet Explorer is an example of an [blank_start]Application[blank_end] layer protocol
Answer
  • Application
  • Presentation
  • Transportation

Question 4

Question
Ethernet is an example of a [blank_start]Data Link[blank_end] layer protocol
Answer
  • Data Link
  • Physical
  • Transport

Question 5

Question
T1 can be considered a [blank_start]Physical[blank_end] layer protocol
Answer
  • Physical
  • Data-Link
  • Session

Question 6

Question
Layer 2 of the OSI model is the [blank_start]Data Link layer[blank_end], which provides the physical transmission of the data and handles error notification, network topology, and flow control
Answer
  • Data Link layer
  • Physical
  • Network
  • Presentation

Question 7

Question
[blank_start]Cable modems[blank_end] use RG-6 [blank_start]coax[blank_end] cables
Answer
  • Cable modems
  • coax

Question 8

Question
To get the high data-transfer speed, like 1 Gbps, you need to use a wire standard that is highly rated, such as [blank_start]Category 5e or Category 6[blank_end]
Answer
  • Category 5e or Category 6
  • Category 6 or GigE
  • Coax

Question 9

Question
To connect two switches together or a hub to a switch, you need a [blank_start]crossover[blank_end] cable
Answer
  • crossover
  • ethernet
  • switch

Question 10

Question
One of the biggest benefits of using switches instead of hubs in your internetwork is that each switch port is actually its own [blank_start]collision[blank_end] domain.
Answer
  • collision
  • broadcast
  • anycast

Question 11

Question
Switches can’t break up [blank_start]broadcast[blank_end] domains.
Answer
  • broadcast
  • collision
  • multiple

Question 12

Question
To connect remote LANs together through something known as a [blank_start]wide area network[blank_end]
Answer
  • wide area network
  • local area network
  • campus area network

Question 13

Question
[blank_start]local area network (LAN)[blank_end] is usually restricted to spanning a particular geographic location such as an office building, a single department
Answer
  • local area network (LAN)
  • campus area network (CAN)
  • wide area network (WAN)

Question 14

Question
A [blank_start]router[blank_end] can connect the two LANs.
Answer
  • router

Question 15

Question
the users on each [blank_start]LAN[blank_end] enjoy much faster response times when accessing resources, and administrative tasks are a lot easier, too.
Answer
  • LAN

Question 16

Question
[blank_start]Workstations[blank_end] are often seriously powerful computers that run more than one central processing unit (CPU) and whose [blank_start]resources[blank_end] are available to other users on the network to access when needed
Answer
  • Workstations
  • resources

Question 17

Question
A [blank_start]client[blank_end] machine is any device on the network that can ask for access to resources like a printer or other hosts from a server or powerful workstation.
Answer
  • client

Question 18

Question
The terms workstation, client, and [blank_start]host[blank_end] can sometimes be used interchangeably. Computers have become more and more powerful and the terms have become somewhat fuzzy because [blank_start]hosts[blank_end] can be clients, workstations, servers, and more! The term [blank_start]host[blank_end] is used to describe pretty much anything that takes an IP address.
Answer
  • host
  • host
  • host

Question 19

Question
[blank_start]Servers[blank_end] are also powerful computers. They get their name because they truly are “at the service” of the network and run specialized software known as the network operating system to maintain and control the network
Answer
  • Servers

Question 20

Question
In a good design that optimizes the network’s performance, [blank_start]servers[blank_end] are highly specialized and are there to handle one important labor-intensive job . This is not to say that a single [blank_start]server[blank_end] can’t do many jobs, but more often than not, you’ll get better performance if you dedicate a [blank_start]server[blank_end] to a single task.
Answer
  • servers
  • server
  • server

Question 21

Question
[blank_start]host[blank_end] means any network device with an IP address.
Answer
  • host

Question 22

Question
[blank_start]WAN[blank_end] networks are what we use to span large geographic areas and truly go the distance. Like the Internet, [blank_start]WAN[blank_end]s usually employ both routers and public links, so that’s generally the criteria used to define them
Answer
  • WAN
  • WAN

Question 23

Question
[blank_start]WAN[blank_end]s can utilize either private or public data transport media such as phone lines.
Answer
  • WAN

Question 24

Question
[blank_start]WAN[blank_end]s usually need a router port or ports, span larger geographic areas and/ or can link disparate locations, but are usually slower.
Answer
  • WAN

Question 25

Question
In an internetwork, hosts still use hardware [blank_start]addresses[blank_end] to communicate with other hosts on the LAN. However, they use [blank_start]logical[blank_end] addresses (IP addresses) to communicate with hosts on a different [blank_start]LAN[blank_end] (other side of the router)
Answer
  • logical
  • LAN
  • addresses

Question 26

Question
Each connection into a [blank_start]router[blank_end] is a different [blank_start]logical[blank_end] network.
Answer
  • router
  • logical

Question 27

Question
[blank_start]Multiprotocol Label Switching[blank_end] (MPLS) stands for?
Answer
  • Multi-protocol Label Switching

Question 28

Question
[blank_start]MPLS[blank_end] has become one of the most innovative and flexible networking technologies on the market, and it has some key advantages over other [blank_start]WAN[blank_end] technologies
Answer
  • MPLS
  • WAN

Question 29

Question
[blank_start]Physical[blank_end] layout flexibility Prioritizing of data Redundancy in case of link failure One-to-many connection [blank_start]MPLS[blank_end] is a switching mechanism that imposes [blank_start]labels[blank_end] (numbers) to data and then uses those [blank_start]labels[blank_end] to forward data when it arrives at the MPLS network
Answer
  • Physical
  • MPLS
  • labels
  • labels

Question 30

Question
The [blank_start]labels[blank_end] are assigned on the edge of the MPLS network, and forwarding inside the MPLS network (cloud) is done solely based on labels through [blank_start]virtual[blank_end] links instead of physical links
Answer
  • labels
  • virtual

Question 31

Question
Computers connected together in [blank_start]peer-to-peer[blank_end] networks do not have any central, or special, authority— they’re all [blank_start]peer[blank_end]s, meaning that when it comes to authority, they’re all equals
Answer
  • peer-to-peer
  • peer

Question 32

Question
Computers coexisting in a peer- to-peer network can be [blank_start]client[blank_end] machines that access resources and [blank_start]server[blank_end] machines and provide those resources to other computers. This actually works pretty well as long as there isn’t a huge number of users on the network, if each user backs things up locally, and if your network doesn’t require much [blank_start]security[blank_end]. If your network is running Windows, Mac, or Unix in a local LAN workgroup, you have a [blank_start]peer-to-peer[blank_end] network.
Answer
  • client
  • server
  • peer-to-peer
  • security

Question 33

Question
peer-to-peer networks definitely present [blank_start]security-oriented[blank_end] challenges
Answer
  • security-oriented
  • layout-oriented
  • backup-oriented

Question 34

Question
the [blank_start]physical[blank_end] topology of a network is also a type of map. It defines the specific characteristics of a network, such as where all the workstations and other devices are located and the precise arrangement of all the [blank_start]physical[blank_end] media such as cables.
Answer
  • physical
  • physical

Question 35

Question
a network’s physical topology gives you the lay of the land and the [blank_start]logical[blank_end] topology shows how a digital signal or data navigates through that layout.
Answer
  • logical

Question 36

Question
the [blank_start]bus[blank_end] topology consists of two distinct and terminated ends, with each of its computers connecting to one [blank_start]unbroken[blank_end] cable running its entire length.
Answer
  • bus
  • unbroken

Question 37

Question
Some of the benefits of using a bus topology are that it’s [blank_start]easy[blank_end] to install and it’s not very expensive, partly because it doesn’t require as much [blank_start]cable[blank_end]
Answer
  • easy
  • cable

Question 38

Question
[blank_start]fault tolerance[blank_end] is the capability of a computer or a network system to respond to a condition automatically, often resolving it, which reduces the impact on the system.
Answer
  • fault-tolerance

Question 39

Question
A [blank_start]star[blank_end] topology’s computers are connected to a central point with their own individual cables or wireless connections. You’ll often find that central spot inhabited by a device like a hub, a switch, or an access point.
Answer
  • star

Question 40

Question
Star topology offers a lot of advantages over bus topology, making it more widely used even though it obviously requires more [blank_start]physical[blank_end] media. One of its best features is that because each computer or network segment is connected to the [blank_start]central[blank_end] device individually, if the cable fails, it only brings down the machine or network segment related to the point of [blank_start]failure[blank_end].
Answer
  • physical
  • central
  • failure

Question 41

Question
Another great thing about a star topology is that it’s a lot more [blank_start]scalable[blank_end]— all you have to do if you want to add to it is run a new [blank_start]cable[blank_end] and connect to the machine at the core of the star.
Answer
  • scalable
  • cable

Question 42

Question
It's the center of a [blank_start]star[blank_end] topology network that can give you the most grief if something goes wrong with it. If that [blank_start]central[blank_end] hub happens to fail, down comes the whole network
Answer
  • star
  • central

Question 43

Question
[blank_start]Ring[blank_end] Topology- In this type of topology , each computer is directly connected to other computers within the same network. It has a lot in common with the [blank_start]bus[blank_end] topology because if you want to add to the network, you have no choice but to break the cable [blank_start]ring[blank_end], which is likely to bring down the entire network! This is one big reason that ring is not ideal.
Answer
  • Ring
  • bus
  • ring

Question 44

Question
[blank_start]Mesh[blank_end] Topology In this type of topology, you’ll find that there’s a path from every machine to every other one in the network
Answer
  • Mesh

Question 45

Question
[blank_start]hybrid[blank_end] mesh topology networks will have quite a few connections between certain places to create redundancy (backup).
Answer
  • hybrid

Question 46

Question
it isn’t a full-on [blank_start]mesh[blank_end] topology if there isn’t a connection between [blank_start]all[blank_end] devices in the network.
Answer
  • mesh
  • all

Question 47

Question
In Mesh Topologies. For each n locations or hosts, you end up with n( n–1)/ 2 connections. This means that in a network consisting of only [blank_start]four[blank_end] computers, you have 4( 4– 1)/ 2, or [blank_start]6[blank_end] connections
Answer
  • 4
  • 6

Question 48

Question
A full mesh physical topology is least likely to have a [blank_start]collision[blank_end], which happens when the data from two hosts trying to communicate simultaneously “[blank_start]collide[blank_end]s” and gets lost.
Answer
  • collision
  • collide

Question 49

Question
Point-to-Point Topology As its name implies, in a point-to-point topology you have a direct connection between [blank_start]two[blank_end] routers or switches, giving you one communication path. The routers in a point-to-point topology can be linked by a [blank_start]serial[blank_end] cable, making it a [blank_start]physical[blank_end] network, or if they’re located far apart and connected only via a [blank_start]circuit[blank_end] within a Frame Relay or MPLS network, it’s a [blank_start]logical[blank_end] network instead.
Answer
  • 2
  • serial
  • physical
  • circuit
  • logical

Question 50

Question
remember that a big drawback to peer-to-peer network sharing is that it’s not very [blank_start]scalable[blank_end]. With this in mind, you probably won’t be all that surprised that even if both machines have a wireless point-to-point connection, this network still won’t be very [blank_start]scalable[blank_end].
Answer
  • scalable
  • scalable

Question 51

Question
What you see here is a lightning bolt and a couple of round things with a bunch of arrows projecting from them, right? Well, the two round things radiating arrows represent our network’s two routers, and that lightning bolt represents a [blank_start]WAN[blank_end] link. These symbols are industry standard, and I’ll be using them throughout this book, so it’s a good idea to get used to them!
Answer
  • WAN

Question 52

Question
a [blank_start]point-to-multipoint[blank_end] topology consists of a succession of connections between an interface on one router and multiple destination routers— one point of connection to multiple points of connection. Each of the routers and every one of their interfaces involved in the [blank_start]point-to-multipoint[blank_end] connection are part of the same [blank_start]network[blank_end].
Answer
  • point-to-multipoint
  • point-to-multipoint
  • network

Question 53

Question
[blank_start]hybrid[blank_end] topology means just that— a combination of two or more types of physical or [blank_start]logical[blank_end] network topologies working together within the same [blank_start]network[blank_end]. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 18). Wiley. Kindle Edition.
Answer
  • hybrid
  • logical
  • network

Question 54

Question
Remember, a [blank_start]star[blank_end] topology really shines when it comes to making additions to the network, moving things around, and making any kind of changes happen quickly, efficiently, and cost effectively. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 20). Wiley. Kindle Edition.
Answer
  • star

Question 55

Question
Here’s a list of things to keep in mind when you’re faced with coming up with the right topology for the right network: - [blank_start]Cost[blank_end] - Ease of [blank_start]installation[blank_end] - Ease of maintenance - [blank_start]Fault-tolerance[blank_end] requirement - and security requirements. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 20). Wiley. Kindle Edition.
Answer
  • installation
  • Fault-tolerance
  • Cost

Question 56

Question
Today’s networks can get pretty complicated, so we need to have a standard way of communicating with each other intelligibly about exactly which part of the network we’re referencing. This is the reason we divide networks into different parts called backbones and [blank_start]segments[blank_end]. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 20). Wiley. Kindle Edition.
Answer
  • segments

Question 57

Question
You can see that the network [blank_start]backbone[blank_end] is actually kind of like our own. It’s what all the network segments and servers connect to and what gives the network its structure. As you can imagine, being such an important nerve center, the [blank_start]backbone[blank_end] must use some kind of seriously fast, robust technology— often Gigabit Ethernet. And to optimize network [blank_start]performance[blank_end]— its speed and efficiency— it follows that you would want to connect all of the network’s servers and segments directly to the network’s [blank_start]backbone[blank_end]. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 20). Wiley. Kindle Edition.
Answer
  • backbone
  • backbone
  • performance
  • backbone

Question 58

Question
When we refer to a [blank_start]segment[blank_end], we can mean any small section of the network that may be connected to, but isn’t actually a piece of, the backbone. The network’s workstations and servers organized into [blank_start]segments[blank_end] connect to the network backbone, which is the common connecting point for all [blank_start]segments[blank_end]; Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 21). Wiley. Kindle Edition.
Answer
  • segment
  • segments
  • segments

Question 59

Question
A [blank_start]campus area network[blank_end] (CAN) refers to a network that encompasses several buildings. It comprises the part of the network where data, services and connectivity to the outside world is provided to those who work in the corporate office or headquarters. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 21). Wiley. Kindle Edition.
Answer
  • campus area network

Question 60

Question
Classic [blank_start]Storage area networks[blank_end] (SANs) are comprised of high-capacity storage devices that are connected by a high-speed [blank_start]private[blank_end] network (separate from the LAN) using a storage-specific switch. This storage information architecture addresses the collection of [blank_start]data[blank_end], management of data, and use of data. These networks are typically fiber networks. Lammle, Todd. CompTIA Network+ Study Guide (Comptia Network + Study Guide Authorized Courseware) (p. 21). Wiley. Kindle Edition.
Answer
  • Storage area networks
  • private
  • data
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