CompTIA A+ Prep Course 4.pdf

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CompTIA A+ Prep Course
Jim Price, CCNA, Security+, A+
 ▪ 90-minute time limit
▪ Maximum of 90 questions
▪ Multiple Choice
▪ Drag & Drop
▪ Performance-based (Simulators)

Core 1 Exam ▪ Passing Score = 675 (75%) on a scale of 100-900
▪ Cost = $253 (in USA)
(220-1101)
Domain %
Mobile Devices 15
[Focus = Hardware] Networking 20
Hardware 25
Virtualization & Cloud Computing 11
Hardware and Network 29
 ▪ 90-minute time limit
▪ Maximum of 90 questions
▪ Multiple Choice
▪ Drag & Drop
▪ Performance-based (Simulators)

Core 2 Exam ▪ Passing Score = 700 (78%) on a scale of 100-900
▪ Cost = $253 (in USA)
(220-1102)
Domain %
Operating Systems 31
[Focus = Software] Security 25
Software Troubleshooting 22
Operational Procedures 22
Hardware
Overview
 Computer Types

Desktop Mobile

Tower Laptop “Smart” Device

Mini PC Desktop Replacement Tablet

All-in-One Ultra Portable Smart Phone

Thin Client Netbook IoT Device
 MEMORY
▪ RAM (Random Access Memory)
▪ Very fast access to data
▪ Volatile – data is lost when power is turned off

Memory and
Storage STORAGE
▪ HDD (Hard Disk Drive) – traditional method
▪ SSD (Solid State Drive) – newer method
▪ Both are non-volatile – data is retained when powered
off
 POWER SUPPLY
▪ Usually internal for desktops
▪ Usually external (mostly) for laptops
▪ Converts AC to DC at several different voltages

Power and
Cooling COOLING
▪ Air cooling (fans) – most common method
▪ Liquid cooling – used in special applications
▪ Heat is the enemy of the internal components –
particularly the CPUs
 CPU (CENTRAL PROCESSING UNIT)
▪ Mounted on the motherboard
▪ Mounted underneath a heat sink and cooling fan
▪ The “brains” of the computer

CPU and
Motherboard MOTHERBOARD
▪ The part to which everything else attaches
▪ Provides power to the CPU and RAM
▪ Makes the electrical (data) connection between all
components
 PORTS
▪ Built in to the motherboard
▪ Allow connection of various external peripheral
devices

▪ Video, audio and network connections, USB
Ports and
Expansion Cards EXPANSION CARDS
▪ Plug into the motherboard
▪ Often provide additional ports
▪ Allow addition of capabilities not found on the
motherboard
 INPUT
▪ Keyboard
▪ Mouse, trackball or touchpad
▪ Touchscreen

Input and Output
OUTPUT
▪ Monitor
▪ Speakers
▪ Printer
▪ Network connection(s)
Motherboards
Hardware
 MOTHERBOARDS
▪ The basis of the entire computer
▪ All hardware communicates through the motherboard
▪ Provides power to some components

Motherboards CHIPSET
and Chipsets ▪ Defines what features are supported, such as:
▪ CPU make and model
▪ RAM type, capacity and speed
▪ Port types
▪ Storage types and RAID support
▪ Expansion slots
▪ Network connections
Typical Motherboard Layout
 Motherboard Form Factors

The motherboard form factor defines the size of the
board, but does NOT directly affect the
performance. It will affect the availability of ports
and slots.

Types of form factors:

ATX (Advanced Technology eXtended)
The largest form factor (EATX)
MicroATX (Advanced Technology eXtended)
A mid-sized form factor
Mini-ITX (Information Technology eXtended)
A much smaller form factor
 PCI (Peripheral Computer Interconnect) expansion
slots are used to attach hardware devices to expand the
capabilities of a computer system beyond what’s
integrated into the motherboard.

PCI slots are the oldest and slowest slots so
should only be used for the sake of
compatibility 32-bit bus allows for 266 MB/s
Mini PCI slots can be found in older mobile
Expansion Slots computers but are not common

- PCI

PCI Slots on a Desktop
 x8 PCIe (Peripheral Computer Interconnect Express) expansion
x16 slots are used to attach hardware devices to expand the
capabilities of a computer system beyond what’s integrated into
the motherboard.

x1 PCIe slots are the latest and fastest slots
Available in different sizes x1, x4, x8, x12, x16 and x32
PCIe Slots on a Desktop Bigger slots offer more lanes to transfer data so offer
increased performance over the smaller slots
Smaller cards will always work in a bigger slot
Expansion Slots Bigger cards can sometimes work in a smaller slot
Mostly used for WiFi adapters and SSD storage
- PCIe Mini PCIe is a common internal expansion for laptops and
desktops
Version Year Transfer Rate
Number Released ×1 ×4 ×8 ×16
1 2003 0.250 GB/s 1.000 GB/s 2.000 GB/s 4.000 GB/s
2 2007 0.500 GB/s 2.000 GB/s 4.000 GB/s 8.000 GB/s
3 2010 0.985 GB/s 3.938 GB/s 7.877 GB/s 15.754 GB/s
4 2017 1.969 GB/s 7.877 GB/s 15.754 GB/s 31.508 GB/s
5 2019 3.938 GB/s 15.754 GB/s 31.508 GB/s 63.015 GB/s
 Front Panel Connectors provide connections for buttons,
switches and lights on the case.

Switches:
Power button
Rest button
Lights
Power LED
HDD LED
Chassis Intrusion
Speaker
Pin Headers

Front Panel Connectors

Front Panel Pin Header
 USB Pin Headers provide a connection to the external USB
ports.

USB
2.0

USB Pin
Headers

USB
3.x
 ATX20 Power Connector

Power
Connectors
ATX24 Power Connector

ATX12v Power Connector
CPU fan connectors are either 3-
pin or 4-pin connectors.

4-pin CPU Fan Connector

Fan Connectors

4-pin Chassis Fan Connector
Front intake with rear and top exhaust

Chassis or Case fans are designed to pull in cool air from the front and expel hot air out the rear,
top or side of the case.
BIOS/UEFI
Hardware/Firmware
 Computer Firmware

The BIOS (Basic Input Output System) or UEFI
(Unified Extensible Firmware) initiates the boot
process and is used to manage the integrated
hardware features on the motherboard.
ROM (Read-Only Memory) chips are used to
store the BIOS/UEFI
EEPROM (Electrically Erasable Programmable
Read-Only Memory) chips are used in modern
systems
Enable updating BIOS/UEFI via a flashing
process
Updates enable compatibility with new
hardware or fix security vulnerabilities
UEFI-Only Features
Secure Boot: Blocks untrusted code from
running at boot
Faster Startup
Mouse and Keyboard Interaction
 CMOS (Complimentary Metal –Oxide Semiconductor

The CMOS is used to store configuration changes to the BIOS/UEFI.

CMOS Setup Utility is accessed by pressing “Delete”, “F2” or another key during boot
EEPROM (Electrically Erasable Programmable Read-Only Memory) chips are used in
modern systems
Enable updating BIOS/UEFI via a flashing process
Updates enable compatibility with new hardware or fix security vulnerabilities
CMOS is volatile memory
Requires power to keep data
CR2032 battery provides that power
Reverts to default settings if power is lost

CR2032 battery Clear CMOS Jumper Clear CMOS Switch
 Common CMOS Settings

Boot Device Priority – controls the order of the
drives from which the computer will boot
Enable/Disable Access to Ports
USB
Thunderbolt
Serial
Network
Wake-on-LAN (WoL)
Virtualization Support AMI BIOS Setup Utility
Intel-VT/VT-d or AMD-V
Overclocking
CPU multipliers and voltages
RAM timing and voltages
Interface Configurations
Security Features
BIOS/UEFI Passwords
Trusted Platform Module (TPM)
Hardware Security Module (HSM)
ASUS UEFI BIOS Utility
 POST (Power On Self Test) and POST Cards

The Power On Self Test is a routine check of the hardware in the
computer. This is the first thing that occurs when you power a
computer on. If a component fails, the computer will beep or
generate error codes to indicate which component is failing.

Sample POST Beeps:
Single Beep – usually a good sign; everything is ok
Long Repeating Beep – often indicates a problem with RAM
One Long Beep and Three Short Beeps – may indicate a video card
problem
These Beep Codes are manufacturer (and sometimes model) specific.
Check the manufacturer’s website for beep codes.

POST Cards will display an error code indicating the component
which is failing. Once again, these are typically manufacturer (and
sometimes model) dependent.
CPUs
Hardware
 Central Processing Unit (CPU) and Architecture

The CPU (Central Processing Unit) is a core component, and the “brains” of all computing devices. The
CPU processes instructions for the operating system (OS), applications and other components. The
motherboard chipset and socket determine CPU compatibility. There are two primary CPU architectures:

x86/x64:
CISC (Complex Instruction Set Computing) based architecture which includes many instructions to
perform many diverse tasks
Designed with desktop and server systems in mind
Intel and AMD dominate this market space
Consumes lots of power and generates lots of heat
Large library of compatible software

ARM (Advanced RISC Machine):
RISC (Reduced Instruction Set Computing) based architecture includes much fewer instructions than
x86/x64
Designed with mobile and portable computers in mind
Qualcomm, Samsung, Nvidia, Apple, and many others compete in this space
Power efficient and generates less heat
Limited software compatibility but growing quickly
 Desktop and Server CPU Sockets

PGA (Pin Grid Array) Sockets:
Connector with holes to receive pins on the bottom of the CPU
Older style still used by AMD for some Ryzen CPUs

LGA (Land Grid Array) Sockets:
Connector with pins that contact the pads on the bottom of the CPU
Intel created and exclusively uses LGA sockets
Used by AMD for their Ryzen Threadripper and EYPC CPUs

AM4 PGA Socket AMD Ryzen CPU LGA1700 Socket Intel Core i-Series CPU
 Server CPU Sockets

Multi-socket Motherboards:
Some server motherboards have multiple CPU sockets to provide high performance
Can be either LGA or PGA socket types but never both

Dual LGA CPU Motherboard Quad LGA CPU Motherboard
 Sockets and Processors

Socket Generation Intel CPUs Socket Pins Style AMD CPUs
LGA 1155 2nd & 3rd AM3+ 942 PGA FX Vishera, FX Zambezi

LGA 1150 4th FM2 904 PGA A-Series

LGA 2011 3rd, 4th, & 5th Core i3/i5/i7/i9, FM2+ 906 PGA A-Series

LGA 1151 6th, 7th, 8th, & 9th Pentium, Celeron, Xeon AM4 1331 PGA Ryzen, Athlon, A-Series

LGA 1200 10th & 11th TR4 4094 LGA Ryzen Threadripper

LGA 1700 12th sTRX4 4094 LGA Ryzen Threadripper

High-Performance CPUs Mainstream CPUs Budget CPUs Server CPUs
Core i3, Pentium and
Intel Core i9 Core i5 and i7 Xeon
Celeron

AMD Ryzen Threadripper Ryzen Athlon and A-Series EYPC
 Mobile CPU Sockets

Mobile CPUs are designed to be smaller and more power efficient than desktop CPUs to better fit
needs of mobile users. Laptops use BGA sockets.

BGA (Ball Grid Array) Sockets:
There is no connector, instead balls of solder on used to attach the CPU to the board
Intel and AMD use them for their mobile CPUs

BGA Style Intel Core i7-5500U
 Clock Speed
Clock speed is an indicator of performance, how fast a
CPU can process data.. A higher frequency indicates
faster performance. Clock speed is measured in cycles
per second (Hertz = Hz) or multiples of that. For example,
1000 MHz = 1 GHz.

32-bit and 64-bit
This is a measure of how many bits a processor can
address in a single cycle. 64-bit is the current standard,
but you may run across some older 32-bit machines.
CPU Technology 32 Bit CPU 64 Bit CPU
x86 / 32-bit Software
x64 / 64-bit Software
Maximum RAM 4 Gigabytes 16 Terabytes

Windows 10
Windows 11
macOS
Linux
 Multithreading
Hyper-Threading is an Intel based technology which
allows a CPU core to process multiple instructions
instantaneously. Referred to as Simultaneous
multithreading (SMT) by other manufacturers like AMD.

Multicore
A multicore processor is a single chip that has two or
more processor cores attached
Provides enhanced performance and reduced power
consumption
CPU Technology Enables more efficient simultaneous processing of
multiple tasks
Dual-Core, Quad-Core, Hexa-Core and Octa-Core
processor are common in all computing devices
Dual core Dual core
Single core 1GHz CPU 1GHz CPU
1GHz CPU
App App
App 1 App App 1 2
1 2 App App
App 2 3 4

Multithreading Multicore Multicore with
Multithreading
 Virtualization Support
Virtualization support allows a system to host virtual
machines (VMs)
NOT all CPUs support this feature, check manufacturers’
documentation
Can be enabled or disabled in the BIOS/UEFI utility
Intel Virtualization Technology (Intel VT)
Also known as Intel VT-d in a BIOS/UEFI menu
AMD Virtualization Technology (AMD-V)
Also known as Secure Virtual Machine in a
BIOS/UEFI menu
CPU Technology
 ▪ Throttling a CPU is done to reduce power consumption
and so the CPU generates less heat. Modern CPUs will
reduce their clock speed if they become too hot.
▪ Intel calls its throttling technology “SpeedStep”
▪ AMD calls their throttling technology “Cool’n’Quiet”

▪ Overclocking a CPU will increase the CPU frequency by
increasing the multiplier to get better performance.

CPU Technology ▪ Supplying a better cooling solution is a must when
overclocking; liquid cooling is recommended.
▪ Only recommended for gamers.

▪ Clock Multipliers are used to change the ratio of the base
clock and the external clock often modified to overclock a
CPU.
▪ CPU clock x Clock multiplier = CPU frequency.
▪ 150 MHz x 10 = 1,500 MHz/1.5 GHz
 System Cooling – Passive Cooling

Passive cooling techniques do NOT use any moving parts.

Thermal Compounds are a paste or grease that’s applied to the top
of a chip to assist in moving the heat away from a chip
Fills in the microscopic imperfections in the CPU aluminum lid
Conducts heat away from the CPU and into the heat sink
Must be replaced if it becomes dry and brittle
Thermal pads are soft rubber pads that are an alternative to thermal
compounds
Last longer than thermal compound but not as good at
transferring heat
Commonly used on memory chips
NOT commonly used with CPUs
Heat Sinks are blocks of metal that absorb the heat from the chip on
which they sit
Commonly used with CPUs, memory, SSDs, GPUs, and chipsets
Before you install a heat sink, you must always apply thermal
compound
 System Cooling – Active Cooling

Active cooling techniques DO use moving parts.

CPU Fan/CPU Cooler
Includes a heatsink with a fan mounted on it
If a system is overheating, consider replacing the stock cooler
with a more efficient one
Compatibility is based on the CPU socket type
Case Fans
Intake fans pull in cool air
Exhaust fans push out the hot air

200mm 92mm 80mm 60mm 40mm
Case Fans from 200mm – 40mm
 System Cooling – Advanced Cooling

Liquid cooling uses either water or coolant to transfer heat as quickly as possible.

Liquid cooling:
Can be very dangerous because the risk of a leak
Liquid cooling kits can be more efficient but require regular maintenance
All-in-one coolers do NOT require regular maintenance but may not be as efficient
Only recommended if overclocking or gaming

All-in-one (AIO) Liquid Cooler

Full liquid cooling kit
 ▪ Installation Problems
▪ Fan doesn’t spin: Verify fan and power connections, most
systems will not boot if a CPU fan is not connected.
▪ No activity: If pressing the power button does not
produce any sounds, lights or fan spins then verify the
CPU is seated properly.

▪ Heat Issues
CPU ▪ Loud alarm: CPU is overheating so the system will not
Troubleshooting power on for protection.
▪ Spontaneous shutdown: CPUs have protection against
overheating, which causes them to shutdown when
temperatures get too high. Potential solutions:
▪ Clean the case, fans and grills
▪ Manage cables to clear the air flow path
▪ Reapply thermal paste or replace the CPU cooler
RAM
Hardware
 RAM stands for Random Access Memory,
which is the most common type of system
memory used by current computing devices. All
applications that are open on a system require
some amount of memory, so the higher capacity
of RAM the more applications that can be opened.
There are typically two types of RAM used:

SRAM: Static RAM is memory that is often
RAM used as cache inside of CPUs, hard drives,
LCDs and other components. It is soldered
directly to the component, so it is NOT a
serviceable part. This type of RAM is often
referred to as ‘cache”.

DRAM: Dynamic RAM is the memory that is
installed on the motherboard. DRAM comes in
“sticks” that vary in capacity. Common sizes
range from 2GB to 32GB, but larger sizes are
available
 RAM Form Factors

RAM is available in two form factors: DIMM and SODIMM. These differ in size, but should be
the same in performance if all other factors are the same.

DIMM (Dual Inline Memory Module) sticks are commonly found in desktops and servers.

SODIMM (Small Outline Dual Inline Memory Module) sticks are commonly found in
laptops and Small Form Factor (SFF) systems.
 Double data rate (DDR) is the advanced version
of synchronous dynamic random-access memory.
DDR RAM is available in various types (DDR,
DDR2, DDR3, DDR4, DDR5)

Different types of DDR RAM are NOT
compatible with each other
A motherboard that supports one type of DDR
RAM will NOT work with any other type
DDR RAM
Performance Rating
DDR-266 = PC-2100
266 x 8 = 2128
Transfer Bits Mbps
Rate
 DDR RAM Comparisons

DDR RAM is currently available in DDR3, DDR4 and DDR5.

Type Min Speed Max Speed Pins

DIMM: 240
DDR3 DDR3-800 / PC3-6400 DDR3-2133 / PC3-17000
SODIMM: 204

DIMM: 288
DDR4 DDR4-1600 / PC4-12800 DDR4-3200 / PC4-25600
SODIMM: 260

DIMM: 288
DDR5 DDR5-4800 / PC5-38000 DDR5-6600 / PC5-52800
SODIMM: 262
 Memory Channels

Memory channeling allows a system to access more RAM simultaneously to improve performance.

Channels Configuration Description
Single Channel No requirements System can access a single chip at a time

Dual Channel Matching pairs System can access two chips at once

Triple Channel Matching threes System can access three chips at once

Quad Channel Matching fours System can access four chips at once

Single Channel Dual Channel
 ▪ Latency measures how responsive RAM is when data
is being read from it. In other words, how quickly does
it respond? This is measured as a CAS level, or in
milliseconds. Lower is better in either measurement.
▪ ECC (Error checking and correcting) RAM can
detect and fix errors in data on RAM. This type isn’t
RAM Latency common except on critical servers. It makes the system
more stable, but is slower due to the additional
and Variations processes.

▪ Registered and Buffered Memory includes extra
chips to allow for more consistent communications
between the memory controller and RAM. This type is
only found in high memory capacity servers.
Unbuffered memory is common for other systems.
 ▪ Maximum capacity is predetermined. Check the
manufacturer’s specifications.

▪ RAM type is critical because only one will be
supported by the motherboard.

▪ RAM Form Factor is also critical. A SODIMM will not
RAM fit on a desktop motherboard, and a DIMM will not fit in
Replacement a laptop.

Considerations ▪ RAM speed should match the motherboard’s
supported speed, but this is not an absolute
requirement for compatibility.

▪ Number of slots will determine how many sticks of
RAM can be installed.
 ▪ Motherboards produce a long repeating beeps when
there’s a problem with RAM. A blank display is also a sign
of that there might be RAM issues since most newer
systems do not beep.
▪ Verify the DIMMs are seated properly. They can lose
contact because of dust or dirt. They can also experience
chip creep, which occurs from the heating and cooling of the
RAM.

RAM ▪ BIOS/UEFI reports incorrect configuration of RAM
capacity or channeling.
Troubleshooting ▪ Verify the DIMMs are installed in the correctly paired slots.
Often the color of the slots is enough guidance but if in doubt
check the manufacturers manual/website.

▪ Memory or address errors when using the system can be
a sign of faulty RAM. ESD or damage from the factory can
cause RAM to fail.
▪ Replace the suspect RAM with known good working RAM and
see if the problems persist.
Power
 Power Supply Units

A Power supply unit (PSU) is a critical component since it provides
power to the motherboard and all other components attached to it.

Wattage rating identifies the total amount of power a PSU can
deliver
500 watts is what CompTIA recommends as a standard PSU
Match the wattage when replacing a PSU or get one with a
higher wattage, never lower
Non-Modular PSUs have all the cables permanently attached
Can take up space and reduce airflow Non-Modular PSU
Modular PSUs don’t have any cables attached, just connectors
Only need to attach the cables that are needed
Redundant Power Supplies are found on critical servers to
prevent system downtime if a PSU fails. These are NOT found
on consumer class systems

Fully Modular PSU
 ATX versus SFX

ATX power supplies are used in computer cases
that support ATX and micro-ATX motherboards

SFX power supplies are used in computer cases
that support Mini-ITX or smaller form factors

Power Supply
Form Factors

SFX and ATX PSUs
 Power Supply Connectors

Molex Power Connector
▪ Supplies 5v and 12v
▪ Used by IDE drives, case fans, and other devices
▪ Also known as the Standard connector

SATA Drive Power Connector
▪ Supplies 5v, 12v and 3.3v
▪ Used on SATA drives only

PCIe power connector
▪ Used to give additional power to PCIe video cards
▪ 6 pin supplies 75 watts
▪ 8 pin supplies 150 watts
 Power Supply Connectors

ATX Connector
▪ Supplies 5v, 12v and 3.3v
▪ Gives power to the motherboard
▪ Comes in a 20 pin and 24 pin version

ATX12v
▪ 4 pin connector also known the P4 connector
▪ Connects to the motherboard to give power to the CPU
 Power Supply Troubleshooting

A Power Supply Unit may fail completely or partially. With a complete failure, nothing inside the case
will power on. With a partial failure, some components receive power, while other don’t. PSUs are a
Field Replaceable Unit (FRU) and can be replaced. Some PSUs have a voltage switch for either US or
European voltages. Make sure that is set correctly.

Multimeter – measures voltage, Power Supply Tester – can
resistance, current and other metrics automatically identify if a PSU is
failing and needs to be replaced

Power Supply Tester
Multimeter
 Power Supply Troubleshooting – AC Outlets

AC power outlets connect electrical equipment to the alternating current
(AC) mains power in our homes and offices.

Damage to devices and fire can occur if the outlet is wired incorrectly.
A multimeter can be used to confirm power is available at the outlet
and that the voltage is correct
An AC Outlet Tester can be used to identify if the outlet is wired
correctly
DO NOT try to repair an outlet that is incorrectly wired. Report it
immediately. Only a trained and licensed electrician should repair
or replace an outlet at a commercial site.
Neutral

Hot
120 volts

Ground
AC Outlet Tester
Standard AC Outlet
 A Surge Protector/Suppressor
is a simple device that offer
protection against power spikes
(surges). Computing
equipment and peripherals
should always be connected to a
Power surge protector instead of
directly to an AC outlet. The
Protection Joule rating indicates how
much energy it can absorb
before it fails. The higher the
Joule rating, the better the
protection. CompTIA
recommends a minimum 600
Surge Protector
joules.
 A UPS (Uninterruptible Power Supplies) is a battery backup that
will keep your critical equipment powered even when there is a
disruption in electrical service. These provide surge protection as
well as protection against brownouts and blackouts.

UPS Considerations:
Load identifies how much power it can deliver
Run time indicates how long it can power devices
Devices that should be UPS-protected include servers, critical
computers and monitors as well as critical networking
equipment
Power
Protection

UPS font and rear view
 Power Supply Splitters and Adapters

Adapters are useful when a PSU lacks a required connector, they convert
one connector to another connector.

Splitters can multiply a connector and convert it.

Molex to SATA Splitter Molex to PCIe Adapter ATX20 to ATX24 Adapter
Storage
 ▪ Capacity defines how much data can be stored, and is
measured in megabytes (MB), gigabytes (GB), or
terabytes (TB).

▪ Performance defines how fast data can be read or
written, and is measured in bits per second (bps),

Storage megabits per second (Mbps), or gigabits per second
(Gbps). This is also known as throughput.
Terminology ▪ Interface is how the drive connects to the computer
system. Typical internal interfaces are SATA and m.2.
Typical external interfaces are USB and Thunderbolt.
This is also known as the connector.

▪ Form factor defines the dimensions of the disk.
 Hard Disk Drive (HDD)

Hard Disk Drives use a magnetic head to read/write data
onto spinning metal or ceramic platters.
Available in 2.5” and 3.5” form factors
Commonly connected to SATA interfaces
Also found in legacy interfaces such as IDE/PATA and SCSI
Advantages
Affordable in large sizes up to 22TB
Disadvantages
Not ideal for mobile since there are many moving parts
Slower at reading and writing data than an SSD Inside 3.5” drive

Platter Speeds Common use Sizes
5,400 RPMs Laptop/Notebooks 2.5” and 3.5”
7,200 RPMs Desktops 2.5” and 3.5”
10,000 RPMs Gaming and servers 3.5”
15,000 RPMs Enterprise and data centers 3.5”
2.5” and 3.5” Drives
 Solid State Drive (SSD)

Solid State Drives (SSD) uses an array of NAND flash chips to
read and write data electrically.
Available in SATA and M.2 form factors
Advantages
Ideal for mobile since there are no moving parts
Faster at reading/writing data
Disadvantages
More expensive than traditional HDDs
Price per GB is how we determine the relative
value of the drive SATA SSD out of its shell
1TB HDD sells for about $30, that’s $30/1000GB
= $3 per gigabyte
1TB SSD sells for about $100, that’s
$100/1000GB = $10 per gigabyte
Limited write cycles
Writing to NAND chips degrades their ability to M.2/NVMe SSD
store data
Reading from NAND chips does NOT degrade
them
 Solid State Hybrid Drive (SSHD)

Solid State Hybrid Drives are mostly HDDs with a much
smaller portion of SSD storage.
Available in 2.5” and 3.5” form factors
Prioritize frequently used files and places them in the SSD
portion for faster loading
SSD capacity can range from 8GB to 32GB
Advantages
Bigger space at a lower cost than an SSD
Some files will open faster
Disadvantages
Not ideal for mobile since there are many moving parts
Not all files will open quickly
 SATA Connections

SATA (Serial ATA) is a connector used to attach storage devices
such as HDDs, SSDs, and optical drives.
Connector is ambidextrous; either end can connect to the
motherboard or the drive
All SATA types are compatible with each other
Hot swappable drives
Replaced the older PATA/IDE connector
Mini SATA (mSATA) is a smaller version found in SFF systems 6 SATA ports

SATA Versions
Type Max Speed
SATA 1 1.5 Gbps / 150 MB/s
SATA 2 3 Gbps / 300 MB/s
SATA 3 6 Gbps / 600 MB/s

SATA Cable Mini SATA (mSATA)
 SATA Drives

SATA Drive Form Factors
3.5-inch drives
Large form factor used in desktop and server systems
Drive sizes up to 22TB
Available in both HDD and SSD
2.5-inch drives
Small form factor used in portable, desktop, and 2.5” and 3.5” SATA Drives
server systems
Drive sizes up to 5TB
Available in both HDD and SSD
mSATA drives
Small form factor used in portable, desktop, and
server systems
Available in SSD only
mSATA Drive
 M.2 Connections

M.2 connectors have quickly become the preferred SSD
form factor. Key ID Device Supported Standard
Smallest drive form factor B Key SATA SSD SATA
Replaced the older mSATA standard
Supports SATA and NVMe solid state drives M Key NVMe SSD PCIe x2/x4
Formerly NGFF (Next Generation Form Factor) B+M Key SATA or NVMe SSD SATA or PCIe
M.2 slots are “keyed” to identify what type of device or
drive is supported

SATA B+M key SSD NVMe M key SSD
 NVMe (Non-Volatile Memory Express) Connections

NVMe (Non-Volatile Memory express)
PCIe based SSD drive which provides the best
performance
Fastest SSDs on the market
Available in different lengths

NVMe to PCIe Adapter
 Legacy Storage Connections

IDE/PATA SCSI
166 MBps maximum data rate 320 MBps maximum data rate
40-pin ribbon connector 80-pin ribbon connector
1 connector supports 2 drives 1 connector supports many drives
 Removable Storage – External Drives

External Drives are a convenient way to
Connector Speeds Power Portable Drives
expand storage
Available in HDD or SSD eSATA 1.5Gbps - 6Gbps No
Available in various connector types
3.5” drives require AC power USB 480Mbps - 40Gbps Yes
2.5” drives may be powered from the Thunderbolt 10Gbps - 80Gbps Yes
data port

USB3.0 & eSATA drive

Thunderbolt drive
 Removable Storage – External Drive Enclosures

External Drive Enclosures can be used to make an internal drive into an external one.
Useful if you have a spare drive you want to make into a portable or back drive.
Available in SATA and NVMe drive compatibility with USB, thunderbolt and eSATA as
connection.

NVMe thunderbolt enclosure

2.5” SATA USB enclosure
 Removable Storage – Flash Memory Devices

USB Thumb/Flash/Pen Drives
Faster, larger, and more durable than floppy disks or optical media
Meant to be used to transport data
Should NOT be used as persistent storage like a hard drive
Memory Cards/Storage Cards
Used in portable devices like smartphones, cameras, tablets, and game consoles
Many formats exist; SD, miniSD, microSD, CompactFlash (CF)
Card readers can be used to connect a storage card if support isn’t included in a device

CompactFlash, SD, and microSD Cards USB flash drive USB card reader
 Removable Storage – Optical Drives

Optical Drive Laser Read Only Media Recordable Media Rewriteable Media Common Sizes
CD Red CD-ROM CD-R CD-RW 700MB
DVD-ROM DVD-RW SS/SL: 4.7GB
DVD Red DVD-R
DVD-Video DVD-RAM SS/DL: 8.5GB
25GB
BD-ROM BD-RE
Bluray Blue BD-R 50GB
BD-Video BDXL
200GB (BDXL)
 ▪ RAID (Redundant Array of Independent Disks)
combines identical hard drives to either increase storage
capacity and performance, provide data protection, or
both. RAID is not specific to any type of drive, can be IDE,
SATA, M.2, PCIe, USB or Thunderbolt.
▪ Hardware RAID
▪ Motherboard built-in RAID
Storage ▪ PCI or PCIe RAID controller card

Redundancy - ▪ USB/Thunderbolt external RAID encloser
▪ Software RAID
RAID ▪ Windows: Dynamic Disk and Storage Spaces
▪ macOS: Disk Utility can be used to create RAID arrays
▪ Linux: Built-in to the Linux kernel as a standard
▪ JBOD (Just a Bunch of Disks) combines disks to form a
large storage space. This does NOT provide any
performance benefit or data protection.
 RAID 0 – Striping

RAID 0 uses disk striping to combine drives into one larger
and faster logical drive. RAID 0
Disk Striping is a method of storage that spreads data bits
across all disks in the array, increasing performance and
capacity
Advantage
Faster read and write because of disk striping A1 A2
Larger storage than any single disk
Only two disks are required, but more disks will A3 A4
increase capacity and performance
Disadvantage – NO Data Protection! A5 A6
If one disk fails all data is lost without a backup
More disks you have the more data you can lose without A7 A8
a backup
 RAID 1 – Mirroring

RAID 1 provides data protection by mirroring data across two RAID 1
disks.
Disk Mirroring actively duplicates bits across two disks to
prevent data loss
Advantage
Data protection - If one disk fails, there is NO data loss A1 A1
Only two disks are required
No performance lost if a disk fails A2 A2
Fast recovery
Disadvantage – Slower! A3 A3
Maximum storage capacity is limited to the size of a
single disk A4 A4
One disk for storage and one for protection
Dual write uses more resources and slows write
performance
 RAID 5 – Mirroring

RAID 5 uses disk striping to combine drives into one
larger and faster logical drive and distributes parity RAID 5
across all disks in the array.
Parity data is a smaller representative value that can
be used to recreate data if data is lost
Advantages
Data protection - If one disk fails, parity will be A1 A2 P1
used to recreate the data
Larger storage than a single drive A3 P2 A4
Disadvantages
Three disks are required. More disks will P3 A5 A6
increase capacity NOT protection or performance
Parity is SLOW! A7 A8 A9
Makes working while a disk has failed slow
Makes rebuilding the array slow when
replacing a degraded disk
 RAID 10 – Nested, striped mirrors

RAID 10 (1+0) combines disk into RAID 1
arrays and then combines those arrays into a
RAID 0.
Parity data is a smaller representative
RAID 10
value that can be used to recreate data if
data is lost RAID 0
Advantages
Faster read and write because of disk
striping A1 A1 A2 A2
Larger storage than any single disk
More disks will increase capacity, A3 A3 A4 A4
performance, and protection
No performance loss if a disk fails A5 A5 A6 A6
Fast recovery
Disadvantages
A7 A7 A8 A8
Four disk minimum RAID 1 RAID 1
If a RAID 1 array fails all data will be
lost - that’s two disks in a single RAID
1 failing
 Comparing RAID Levels

RAID 0 RAID 1 RAID 5 RAID 10 (1+0)
Min # of Drives 2 2 3 4
Max # of Drives Unlimited 2 Unlimited Unlimited
Max # Failures 0 1 1 2 or More
Storage Protection ✘ ✓ ✓ ✓
Larger Storage ✓ ✘ ✓ ✓
Faster Storage ✓ ✘ ✘ ✓
Fast Recovery ✘ ✓ ✘ ✓
Protection Method None Mirroring Parity Mirroring
Storage Method Striping Duplexing Striping Striping
 What to do when a RAID array stops working
RAID 0
Replace any degraded disk, recreate the array,
recover data from a backup.
RAID 1/ RAID 10
Replace the degraded disk, “re-mirror” the
drive during scheduled downtime.
RAID 5
Troubleshooting Replace the degraded disk, “rebuild” the array
during scheduled downtime.
RAID RAID Not Found
This can occur for any number of reasons, follow
standard troubleshooting methodology.
Check cables, power, controller and configurations.
Check drive compatibility
 Light-emitting diode (LED) status indicators

Grinding noises

Clicking sounds

Bootable device not found

Data loss/corruption
Common
Self-monitoring, Analysis, and Reporting
Storage Issues Technology (S.M.A.R.T.) failure

Extended read/write times

Input/output operations per second (IOPS)

Missing drives in OS
Peripheral Ports and
Cables
 Serial Ports

Serial Ports are one of the oldest ports still in use but for very few occasions
Most computers do NOT include a serial port
Serial port can be added via USB, PCI, or PCIe expansion card
Can be used to manage enterprise-class network devices, program microcontrollers, or
control robotic equipment
Also known as the RS-232 (Recommended Standard 232), DB9, COM Port (Communication port)

USB to Serial Adapter Rollover Cable (Console) / Serial to RJ-45
 USB (Universal Serial Bus) Ports

USB (Universal Serial Bus)
Supports keyboards, mouse, storage devices, printers, scanners, webcams, gamepads, ethernet,
WiFi, displays, audio devices, touchscreens.
127 devices can be plugged into a single USB port
3 meters (10 feet) cable length limit

USB Version Speed Color
USB 1.0 Low Speed 1.5 Mbps White
USB 1.1 Full Speed 12 Mbps White
USB 2.0 Hi-Speed 480 Mbps Black
USB 3.0 SuperSpeed 5 Gbps Blue
USB 3.1 SuperSpeed+ 10 Gbps Teal
USB 3.2 SuperSpeed++ 20 Gbps N/A
USB 4 SuperSpeed+++ 40 Gbps N/A
 USB Connectors

Type A Type B Mini B Micro B
USB 1.0 – 2.0 USB 1.0 – 2.0 USB 1.0 – 2.0 USB 1.0 – 2.0

Type A (host port)
Computer connector
Type B (guest port)
Device connector
Type C (host and guest port)
Computer & device connector
Reversable

Type A Type B Micro B Type C
USB 3.0 – 3.1 USB 3.0 – 3.1 USB 3.0 – 3.1 USB 2.0 – 4
 Thunderbolt Ports

Thunderbolt
Fastest and most capable connector
Compatible with DisplayPort and USB devices
Supports storage devices, displays, audio, networking, and adapters
6 thunderbolt devices can be daisy chained using a single thunderbolt port

Thunderbolt Versions Speed Port Type
Version 1 10 Gbps Mini Display Port
Version 2 20 Gbps Mini Display Port
Version 3 40 Gbps USB Type C Mini Display Port

Version 4 80 Gbps USB Type C

USB Type-C
Display Ports
 HDMI (High_Definition Multimedia Interface)

HDMI (High-Definition Multimedia Interface)
HD and UHD audio and video
Most common connector for connecting
computers to monitors and televisions
An active HDMI cable is required for connections
longer than 25 feet
HDCP (High-Definition Copy Protection)
support is required for some HD and UHD content
like Blu-ray video and some streaming services

Standard HDMI, Mini HDMI, and Micro HDMI
 DisplayPort

DisplayPort
HD and UHD audio and video
Support HD digital video and audio signals.
Popularized by Apple and commonly used by gamers to achieve very high refresh rates.
Can be combined with USB and Thunderbolt ports

DisplayPort Cable
 Legacy Video Connectors

VGA (Video Graphics Array) (DB-15)
SD and HD analog video
15pin D-SUB
Normally colored blue VGA Port
DVI (Digital Visual Interface)
VGA Connector
SD and HD analog and digital video
DVI-I supports analog and digital
DVI-A only supports analog
DVI-D only supports digital

DVI Port

DVI Connector
 Video Adapters and Converters

Video adapters can be used to change a video connector from one type to another. They are
simple devices so they cannot convert analog to digital or vice versa.

Video converters can change analog to digital signals since they are more sophisticated
devices.

DisplayPort to HDMI adapter
DVI-I to VGA adapter VGA to HDMI converter
Expansion Cards
 Expansion Cards expand the hardware capabilities of a
computer via PCIe or PCI slots
Add or upgrade USB ports, thunderbolt ports, or storage
connectors (SATA, PATA, NVMe)
Add or upgrade wired or wireless network connections
Add legacy ports like serial, firewire, dial-up modem, and
parallel ports(printer ports)
Video Cards
Adds video processing power and video connectors
Expansion Cards for video output
Sound Cards
Adds audio processing and audio connectors for
audio output
Capture card
Adds video and audio processing and connectors for
input
 Video Cards

Video/Graphic cards process image data and provide a connection for a display
Commonly connects to the PCIe x16 slot
They can be integrated into a motherboard or attached via a PCIe expansion slot.

Dedicated PCIe video card Integrated video ports
Displays
 Resolution is defined by how many pixels make up the
image on the screen.
Standard definition (SD): 640 x 480 ⚫ High definition
(HD): 1920 x 1080
Ultra high definition (UHD)
2K: 2560x1440 ⚫ 4K: 4096x2160 ⚫ 8K: 8192 × 4608
Refresh Rate defines how many screens can be drawn pre
second.
Display High refresh rates provide a smoother experience when
watching videos and playing games or anything with a lot
Terminology of motion.
Low refresh rates can cause eye strain.
Aspect Ration is the ratio of the width and height of the
screen.
4:3 SDTV ⚫ 16:9 HDTV ⚫ 5:4 Computer ⚫ 16:10
Widescreen Computer
 ▪ Brightness increases the intensity of the light which
can improve a dim image.

▪ Viewing Angle will affect at what angles the screen will
be viewable. A wider viewing angle is preferred.
▪ Response Rate is the time it takes a screen to shift the
color of single pixel from black to white and back
LCD again.

Specifications ▪ Contrast Ratio is the measurement of how many steps
between black to white on a screen. A higher contrast
ration will produce an image with darker blacks and
brighter whites.
▪ Color Depth defines how many bits are used to
produce the color of a single pixel. More bits more
colors.
 Twisted nematic (TN)
Fast response rate
Low color accuracy
Very poor viewing angles
Lowest cost
Vertical Alignment (VA)
Slower response rate (slower than IPS)
High color accuracy
Good viewing angles
Higher cost than TN
LCD Screen Lower cost than IPS
In-plane switching (IPS)
Types Slow response rate
High color accuracy
Good viewing angles
Higher cost than TN
Organic Light Emitting Diode (OLED)
Fast response rate
High color accuracy
Prone to burn-in
Highest cost
 Comparing LCD Types

LCD: LCD with CCFL (Cold Cathode Florescent Lamp)
backlight
Thicker than the other types of flat screens.
Requires an inverter to power the backlight.
LED: LCD with LED backlight
Newer style of LCDs that are thinner, have a shaper
picture, and produce a better black levels.
OLED: Organic LEDs produce the picture and the light in a
single element.
Thinnest display type.
Provides the best picture, color, and has the lowest LCD LED OLED
power consumption.
 Projectors

Projectors
Can produce the biggest screen size

“Throws” an image onto a screen or a wall
Best used in low light situations

Lumens are used to measure how bright a projector can 4K BenQ projector
get. Bright rooms require a projector with high Lumens

DLP (Digital Light Processing) is the most common
technology used for projectors.

Common Projector Symptoms
Burned-out bulb
Intermittent projector shutdown

250 inch screen
 VR Headsets

VR headsets provide an immersive
experience by displaying an image which
covers your entire field of view.

They may require many connections
2 HDMI or DisplayPort for each screen,
one for each eye.
1 USB or Thunderbolt connections for
sensors that can be built into the headset
to sense movements.
Other connections might be required for
additional sensors around the room.
 ▪ No image on the screen
▪ Verify the screen is powered-on and that the power cable is
plugged in
▪ Check the video connectors at both ends
▪ Check the input data source
▪ Try a known good video cable or power cable
▪ Spontaneous shutdown
▪ Displays and projectors can overheat which can cause them
Display to shut down to prevent permanent damage

Troubleshooting ▪ Dead pixels
▪ A pixel that has died will appear black dot on the screen
▪ This cannot be repaired; the screen will have to be replaced
if it cannot be tolerated

▪ Dim image
▪ First check the brightness settings and the backlight
settings on the display
▪ Backlights can burn out or an inverter can fail
 ▪ Flashing screen
▪ Unsupported refresh rate
▪ Loose or physically damaged cable

▪ Distorted geometry
▪ LCD screens only support a single native resolution,
Display when they are configured with a non-native resolution,
they might appear stretched or squished.
Troubleshooting ▪ Burn-in
▪ If a static image is left on a screen for too long an
impression of the image can remain on the screen
▪ Prevent burn-in using a screen saver to dim the display
or change the image being displayed
Networking Basics
 ▪ LANs (Local Area Networks) are the private networks
found in homes, offices, and schools. LANs can vary in
size from a single room to an entire building.
▪ SOHO Network
▪ Enterprise/Corporate Networks

▪ WLAN (Wireless Local Area Networks) can exist
within a LAN or on their own.
Local Area
Network (LAN)
 ▪ WANs (Wide Area Networks): When an organization
needs to connect their office on one side of the world to
the other, they connect through a WAN.
▪ The Internet is the public WAN that anyone can get
access to.
▪ Site-to-Site connections are used by large organizations
to connect their different locations over private WAN
links.
Wide Area
Network (WAN)

The Internet Site-to-Site
 ▪ MANs (Metropolitan Area Networks) spread across a
single city.
▪ Connections between the sites are often privately owned
and managed by the organizations that use them.

Metropolitan
Area Network
(MAN)
 ▪ CANs (Campus Area Networks) spread across a
limited geographical distance like a
college/corporate/military campus.
▪ It is privately owned and managed.

Campus Area
Network (CAN)
 ▪ Personal Area Networks (PANs) are small networks
usually made up of two devices.
▪ These devices can be connected over wired connections
(Ethernet or USB) or wireless connections (Wi-Fi,
Bluetooth, Infrared).

Personal Area
Network (PAN)
PC to a PC over a wired connection PC to a smartphone over a wireless connection

PC to a PC over a wireless connection PC to a printer over a wireless connection
 ▪ A SAN (Storage Area Network) is a dedicated network
that provides consolidated, scalable, and high-
performance storage to servers.
▪ SANs offer several benefits over traditional direct-
attached storage (DAS), including:
▪ Improved performance
Storage Area ▪ By offloading storage processing from servers to the SAN
▪ Increased scalability
Network (SAN) ▪ By adding additional storage devices to the network you can
infinitely expand storage

▪ Improved availability
▪ SANs can improve availability by providing multiple paths to
storage devices.

▪ Reduced costs
▪ SANs can reduce costs by consolidating storage resources and
by eliminating the need for dedicated storage administrators.
 Common Network Resources

Devices
Hubs
Clients Switches
Workstations Routers
Laptops / Notebooks Firewalls
Thin Clients / Terminals Wireless Access Points (WAP)
Smartphones / Tablets Wireless LAN Controllers (WLC)

Other Resources
Printers
Scanners
Servers Video Surveillance
Authentication (LDAP, RADIUS) Voice over IP (VoIP) Phones
Files (SMB, FTP, SFTP, TFTP)
Web (HTTP, HTTPS) Other Services
Mail (POP, IMAP, SMTP) Dynamic Host Configuration Protocol (DHCP)
Proxy (Caching, Web) Domain Name System (DNS)
Telephony (VoIP)
Fax
Application (Databases, System Images, Updates)
Network Cables
 ▪ Transmission Speeds
▪ Copper cables achieve speeds of up to 40 Gigabits
▪ Fiber cables achieve speeds above 100 Gigabits

▪ Transmission Distance
▪ Copper cables can reach distances of 1,100 meters (3,609
feet), though most are limited to 100 meters (about 330 feet)
▪ Fiber cables can reach distances of 40 kilometers (25 miles)

Copper vs Fiber ▪ Noise Immunity
▪ EMI (Electro-Magnetic Interference) is a condition when
signals from a device or cable leak out and disrupt signals of
another device or cable
▪ Copper cables are highly susceptible to interference
▪ Use shielded cables to protect against EMI
▪ Fiber cables are NOT susceptible to EMI since they transmit
light rather than electrical pulses
 Coaxial Cable (Coax)

Coaxial Cable (Coax) is a round cable
often used for cable in satellite and Copper conductor
television connections. Its thick outer
jacket makes it ideal for outdoor use. Insulation
RG-6 is the most common type of coax cable.
▪ Advantages
Metallic shield
Shielding protects against EMI
Long transmission distance (1100 meters)
More affordable than fiber optic cables
▪ Disadvantages Outer jacker
More expensive than twisted pair cable
Copper core can snap if mishandled
 Coax Connectors

BNC Connector
Secure locking connector
Commonly used in the old bus and ring networks
Also used on older, analog CCTV camera systems

Connector Port

F Connector
Twisting hand screw commonly found on cable modems

Connector Port
 Twisted Pair Cables

Twisted Pair cables consist of eight wires that are twisted into four pairs.
This is the most used networking cable in homes and offices.
Twisted Pair Types
STP (Shield Twisted Pair): Has shielding to protect against EMI
UTP (Unshielded Twisted Pair): Does NOT have shielding to protect against EMI

Copper
▪ Advantage Copper
conductor
conductor
Easier to install and manage than
coax or fiber optic cables Color-coded
STP has protection against EMI insulation
Least expensive cable Per-pair metallic Color-coded
▪ Disadvantage shielding insulation
Transmission distance is limited to Overall metallic
100 meters (328 feet) shielding
UTP has no protection against EMI Outer jacker
Outer jacket

STP (Shield Twisted Pair) UTP (Unshielded Twisted Pair)
 Twisted Pair Connectors

RJ11 Connector
4 or 6 pin connector
Found on dial-up modems and analog telephones

Connector Port

RJ45 Connector
8 pin connector
Found on desktops, laptops, servers, routers, switches,
wireless access points, IP phones, printers, IP cameras,
game consoles, smart televisions, and many others
Connector Port
 Twisted Pair Categories

Category Speed Distance Note
100 Used in older networks – needs to be replaced if still
Cat 5 100 Mbps
meters in use!
1,000 Mbps / 1 100 More twist per foot allows it to handle disturbances
Cat 5e
Gbps meters to achieve faster speeds
10,000 Mbps / 10
55 meters
Gbps Includes a piece of plastic to separate the 4 wire
Cat 6 100
1,000 Mbps / 1 pairs which minimizes crosstalk
meters
Gbps
10,000 Mbps / 100 Thicker wires to carry a more powerful signal for
Cat 6a
10Gbps meters longer distance
 Twisted Pair Wiring Standards

There are two standard RJ45 pinouts for the individual arrangement of the wire connections to the
RJ45 connectors within an Ethernet cable: the T568A and T568B standards.
It does not matter which one is followed but in practice T568B is more common

Tips
Both standards start with a striped wire
followed by a solid wire. This pattern continues
from start to finish.
The blue and brown pairs are always in the
same location
Only the orange and green pairs transpose
their position

T568A T568B
 Fiber Optic Cable

Fiber optic cables transmit data using light over flexible glass or plastic.
Commonly used by WAN carriers and service providers’ networks because of their needs for
long-distance connections.
Some enterprises also them for high-speed long-range connections in their LANs

▪ Advantages
NOT susceptible to EMI Fiber strand
Longest transmission distance up to
40km Cladding
Fastest speeds up to 255 Tbps
▪ Disadvantages Coating
Most expensive cable Strengthening
Most difficult to install layer
Difficult to troubleshoot issues
Expensive tools needed for
Outer jacker
installation and troubleshooting
Can’t easily repair cables in the field
Fiber Optic Cable
 Fiber Optic Connectors

ST Connector SC Connector
SC (standard connector /
ST (straight tip)
subscriber connector /
BNC style connector from
square connector)
the late 1980s and 1990s
Snaps-in style connector
Used in SMF installations
Used in SMF and MMF
installations

LC Connector Dual LC Connector
LC (Lucent connection /
Dual LC
local connection / little
connector)
Snaps-in style connector
Snaps-in style connector Small form-factor connector
Small form-factor connector Used in SMF and MMF
Used in SMF and MMF installations
installations
 Network Cable Specifications

EMI Max
Cable Connector Max Speed Conductor Cost
Protection Distance
Coax BNC and F Shielding 1 Gigabit 1100 meters Copper $$$
STP RJ-45 & RJ-11 Shielding 10 Gigabits 100 meters Copper $$
UTP RJ-45 & RJ-11 None 10 Gigabits 100 meters Copper $
Single-Mode
ST, SC, & LC Not susceptible > 100 Gigabits 40 kilometers Glass $$$$$$
Fiber
Multimode Fiber SC, LC Not susceptible > 100 Gigabits 500 meters Glass $$$$$
Network Devices
 Network Interface Cards (NICs) are used to connect
devices to a network
It’s common for NICs to be built-in into modern
computer systems
Each NIC has a unique 48-bit MAC address
The link light and activity lights are used to
trouble connections made to the NIC
Link light verifies the cable is plugged in at
both ends
Network Activity light will blink as data goes through
the interface
Interface Card
Link light Activity light
(NIC)

Connect NIC PCIe NIC
 A Hub is a legacy device used to connect and
manage wired communications in a LAN
Communicates by broadcasting
Uses CSMA/CD (Carrier Sense Multiple
Access/Collision Detection) to manage the
collisions

Hub

A B C
5 port hub
Hub broadcasting data
 A Switch is used to connect and manage wired
communications in a LAN
Forward frames based on MAC addresses
Managed switches vs Unmanaged switches
Managed switches can be configured
Used in enterprise LANs to meet their needs for
enforcing policies
Provide additional functions like VLANs, port
security, DHCP snooping, and dynamic ARP
inspection
Expensive
Unmanaged switches can NOT be configured
Switch Used in SOHO networks
Lower cost

48 port managed switch Switch forwarding traffic
 Routers are used to connect different broadcast
domains to each other
Commonly used to connect a LAN to a WAN (Site to
site or the Internet)
Forwards traffic based on IP Addresses in packets
Can usually DHCP
WAN

Router
Router

Cisco 2901 branch router

LAN
 SOHO Routers are multifunction devices offering
many features beyond routing
Always includes wireless, switching, firewall security,
and DHCP
Can include content filtering, file server, print
server, VPN client and server, and other features
Used to connect a LAN to the Internet
Forwards traffic based on IP Addresses in packets

SOHO Router

Linksys WRT54G WiFi Router
ASUS GT-AX10000T WiFi Router
 Firewalls are security devices used to prevent
authorized access to a LAN from the Internet.
Can be a hardware appliance or host-based
software
The Demilitarized Zone (DMZ) is a segment of the
network that has a lower level of protection; this is
used to intentionally expose a device to the Internet

Public
Internet

Firewall
Cisco ASA 5506-X Firewall
Firewall
Demilitarized
Zone (DMZ)

Private
Fortinet Fortigate 100F Firewall LAN
 Access Points (APs), sometimes called Wireless
Access Points (WAPs), are used to provide and
manage wireless communications in a LAN
Uses Radio Frequencies (RF) to transmit host data
Uses CSMA/CA to manage collisions

Access Point Ubiquiti Unifi AX Pro Access
Point
(AP)
Host A Netgear WAX204A Access
Point

AP Switch

Host B
 Wireless LAN controllers (WLC) are used to manage
multiple lightweight access points through a single
interface
Simplifies the management of large wireless networks
Provides additional security and performance features
Can be a hardware, software, or cloud based
Wireless LAN
Controller
(WLC)
Cisco 3504 WLC
 Wireless Range Extenders are used to expand the
coverage of the current wireless network
They operate on the same frequency and channel as
the current wireless network and should have at
least a 15% overlap
Many access points can be configured to be
extenders

Wireless Range
Extender
Ubiquiti Unifi UAP-Beacon HD
Extender Netgear EX6120 Extender

TP Link EAP225
Extender
 Wireless LAN controllers (WLC) are used to manage
multiple lightweight access points through a single
interface
Simplifies the management of large wireless
networks
Provides additional security and performance
features
Wireless LAN Can be a hardware, software, or cloud based

Controller

Cisco 3504 WLC
 PoE (Power over Ethernet)

Power over Ethernet (PoE) allows you to power devices using just an Ethernet cable.
A PoE switch is required if you want to power many PoE devices
PoE devices are manufactured and sold with PoE built-in as a feature
PoE injectors can be used to power a single PoE device if a PoE switch is NOT available
PoE standards operate at different wattages, verify which is required for your devices

PoE 802.3af PoE+ 802.3at PoE++ 802.3bt
Min Wattage 12.95 watts 25.50 watts 51 watts
Max Wattage 15.40 watts 30.0 watts 60 watts
Max Current 350 mA 600 mA 600 mA

PoE Power Injector
 VLANs (Virtual LANs)

VLANs (Virtual LANs) are used to segment a switch into multiple logical networks
VLANs are statically assigned to managed switch ports
Host can only communicate within their VLAN
Make sure host are connected to the correct VLAN

Sales VLAN 2
Shipping VLAN 3
Engineering VLAN 4
Finance VLAN 5
 VPN (Virtual Private Network)

A Virtual Private Network (VPN) provides secure remote access to a private
network via the public Internet via an encrypted tunnel.
VPN Types:
Site-to-Site
Connects an entire network to another network over the internet
Client-to-Site
Connects an outside host securely to the internal private network over the internet
 SDN (Software-Defined Networking)

Software-Defined Networking SDN Applications
SDNs provide centralized management of network infrastructure by
making use of network controllers
Application Layer Northbound
IDS/IPS, load balancers, proxy servers, and firewalls Interface
Control Layer
Communicates instruction to the network devices based on
Controllers
information gathered from the SDN applications
Infrastructure Layer
Spine-Leaf switches are managed by the controller to provide Southbound
links and access to the host and devices Interface
Management Plane
Provides an interface to the controller via SSH, HTTP/HTTPS, or
an application programming interface (API) Network Objects
Network Services and
Protocols
 The Dynamic Host Configuration Protocol
(DHCP) is used to assign various configurations
to the host of a network.

Common configurations:
Scope is the range of addresses the server can
assign
Example: 192.168.50.100 – 192.168.50.250
DHCP (Dynamic Exclusion range is the range of addresses the
server can NOT assign
Host Reservations allow you to bind a MAC address to a
Configuration specific IP address
Allows DHCP to consistently assign the same IP
Protocol) address to a device without having to manually
configure a static IP address
Lease time defines how long an IP address is
“owned” by a host before it can be assigned to
another host
Available leases identify how many addresses are
still available from the scope
 DHCP Process

4-Step DHCP Process
1. Client: Discover Broadcast
2. Server: Offer Unicast
3. Client: Request Broadcast
4. Server: Acknowledge Unicast
Common Configurations:
IP address
Subnet mask
DNS server
Default gateway
TFTP server and others
 DNS (Domain Name System)

Domain Name Service (DNS): provides
name to IP address resolution for a host.
DNS servers can be in your LAN or out on Where is comptia.org ?
the Internet
A host is normally assigned a DNS server Answer: 104.18.17.29
via DHCP, but it can also be assigned
manually
DNS Server
DNS Name Types Host
Host names identify a specific device in a
network
Hostname = workstation01
Domain names identify a specific
network
comptia.org
Domain name = companyx.lan Web Server
Fully Qualified Domain Name (FQDN)
identify a specific in a specific network
FQDN = workstation01.companyx.lan
 DNS Record Types

Record Type Description Example
A Resolves a name to an IP Address example.com => 123.234.34.56

example.com =>
AAAA Resolves a name to an IPv6 Address 2101:2345:6789:abcd:ef01:2345:6789:abcd

v=spf1 ip4:40.113.200.201
Sender Policy Framework list of hostnames/IP and IPv6 addresses that
TXT (SPF) ip6:2001:db8:85a3:8d3:1319:8a2e:370:7348 include:company.com
mail can be sent from ~all

email_provider._domainkey_.companyx.com
Domain Keys Identified Mail provides authentication of mail being sent
TXT (DKIM) v=DKIM1; p=76E629F05F70 9EF665853333 EEC3F5ADE69A
and received to prevent spam 2362BECE4065 8267AB2FC3CB 6CBE

Domain-based Message Authentication, Reporting, and Conformance
TXT (DMARC) v=DMARC1; p=reject; rua=mailto:[email protected]
controls what happens if authentication fails to prevent spam

CNAME Canonical Name records resolves an alias to a domain name bn.com => barnesandnoble.com

MX Resolves a name to a mail exchanger (email server) imap.gmail.com => 142.250.31.108
 TCP vs UDP

16-bit source port 16-bit destination port
TCP (Transmission Control Protocol) 32-bit sequence number
Reliable 32-bit acknowledgment number
Connection-oriented

24 - 60 bytes
4-bit
Virtual circuit header Reserved Flags 16-bit window size
Sequenced length
Acknowledgements 16-bit TCP checksum 16-bit urgent pointer
24 - 60 bytes (high overhead) Options
Data
UDP (User Datagram Protocol)
Unreliable TCP Segment
Connectionless
16-bit source port 16-bit destination port

8 bytes
No virtual circuit
16-bit TCP checksum 16-bit urgent pointer
Un-sequenced
No acknowledgments Data
8 bytes (lightweight) UDP Segment
 Filesharing Application Protocols

Application Protocol Port Details
File Transfer Protocol is used to share files with users in a LAN or a WAN
FTP TCP 20, 21
Supports authentication, authorization, and directory browsing
Trivial File Transfer Protocol is used to push(put) or pulls(get) files from a server
TFTP UDP 69 Commonly use to manage devices like IP phones, routers and switches
Does NOT support authentication, authorization, or directory browsing
Secure File Transfer Protocol is a secure implementation of FTP
SFTP TCP 22 Supports all the same functions as FTP but with encryption
SFTP is an extension of SSH which is why they use the same port number
Secure Copy Protocol is a secure implementation of TFTP
SCP TCP 22 Supports all the same functions as TFTP but with encryption
TFTP is an extension of SSH which is why they use the same port number

Server Message Block provides file sharing, network browsing, and printing services
SMB TCP 445 Commonly used in Windows networks but supported in Linux, macOS, and many other devices
CIFS(Common Internet File System) is an open implementation used on Linux and macOS

Apple Filling Protocol is an Apple proprietary file sharing protocol available exclusively on
AFP TCP 548
macOS
 Remote Access & Cryptographic Protocols

Remote Access Protocols

Application Protocol Port Details
Telnet provides remote command line access to interact with a server
Telnet TCP 23
Considered insecure and should no longer be used, use SSH instead
Secure Shell provides encrypted remote command line access to interact with a server
SSH TCP 22
SSH version 2 added SFTP and SCP support
Remote Desktop Protocol is used to securely remotely access a Windows desktop
RDP TCP/UDP 3389
Formally known as Windows terminal services

Cryptographic Protocols
Application Protocol Port Details
Secure Socket Layer is a now deprecated cryptographic protocol used in various network
SSL TCP 465
communications like email, web, and VPN to name a few

Transport Layer Security is the replacement for SSL. It supports all the same features with additional
TLS TCP 995
security features.
 Web & Email Protocols

Web Protocols
Application Protocol Port Details
HTTP TCP 80 Hyper Text Transfer Protocol is used to transmit webpages

HTTPS TCP 443 Hyper Text Transfer Protocol Secure is used to securely transmit encrypted webpages using SSL or TLS

Email Protocols
Application Protocol Port Details
POP3 TCP 110 Post Office Protocol downloads incoming mail from a server

IMAP4 TCP 143 Internet Message Access Protocol synchronizes incoming mail from a server

SMTP TCP 25 Simple Mail Transfer Protocol sends outgoing mail to a server

SMTP TLS TCP 587 Secure SMTP over TLS encrypts outgoing mail being sent to a server

IMAP SSL TCP 993 Secure IMAP over SSL encrypts mail being synchronized from a server

POP3 SSL TCP 995 Secure POP3 over SSL encrypts mail being downloaded from a server
 Network Management Protocols

Application Protocol Port Details
NTP UDP 123 Network Time Protocol provides time synchronization

DNS TCP/UDP 53 Domain Name System resolves names to IPv4 and IPv6 addresses

Dynamic Host Configuration Protocol provides various configurations to clients in an IP network
DHCP UDP 67/68 via broadcast
67 is the server port, and 68 is the client port

Bootstrap Protocol provides boot configuration data to clients
BootP UDP 68 Used to boot an operating systems over an IP network
Also used to deploy system images over a network

Simple Network Management Protocol is used to query, configure, and monitor host in a LAN
SNMP UDP 161/162
SNMPv3 encrypts communication where previous versions did not

Service Location Protocol provides network device discovery, allowing computers to find file
SLP TCP/UDP 427
shares and printers
 Network Management Protocols (continued)

Application Protocol Port Details
Lightweight Directory Access Protocol is used in domain-based network environments to
LDAP TCP/UDP 389
facilitate system and user management.

LDAPS TCP 636 Lightweight Directory Access Protocol over SSL is a secure version of LDAP

Syslog is used to store system logs on a central server to assist with troubleshooting network
Syslog UDP 514
issues

Network Basic Input/Output System provides various network communication features in a
Windows network
NetBIOS TCP/UDP 137/139
Used in Windows before IP networking
NetBIOS over TCP/IP is still used in Windows
Network Addressing
 IPv4 (Internet Protocol Version 4) Addressing

IPv4 Address: 32-bit address used to
communicate Reserved Classful Networks
Octet: 8-bit segmentation used for IP
Class 1st Octet Notes
addresses.
Prefix/CIDR: Define how many bits are Class D 224 - 239 Reserved for multicasting
reserved to identifying the network.
Class E 240 - 255 Reserved for scientific research
CIDR (Classless Interdomain Routing)

Useable Classful Networks

Class 1st Octet Number of Host Subnet Mask Prefix/CIDR
Class A 1 – 126 16.7 Million 255.0.0.0 /8
Class B 128 – 191 65 Thousand 255.255.0.0 /16
Class C 192 – 223 254 255.255.255.0 /24
 IPv4 Unicast Addresses

Unicast addresses provide one to one communication.
A unique unicast address is assigned to each host interface.

Unicast Type Address Range Description
Class A: 1.0.0.0 – 126.255.255.255
Public IP Address Class B: 128.0.0.0 – 191.255.255.255 Public addresses are designated to be used on the Internet
Class C: 192.0.0.0 – 223.255.255.255
Class A: 10.0.0.0 – 10.255.255.255
Private IP Address Class B: 172.16.0.0 – 172.31.255.255 Private addresses are designated to be used in LAN
Class C: 192.168.0.0 – 192.168.255.255

Automatic Private APIPA addresses are self assigned by a host when a DHCP request
169.254.0.0 – 169.254.255.255
IP Address(APIPA) fails