Transmission Media in Computer Network

Introduction

The modern global environment is constantly evolving. Data Communication and networking technologies have revolutionized many aspects of modern life. They now depend on computer networks for almost everything. Computers and other types of telecommunication devices may represent data as signals. They are transferred as electromagnetic signals from one device to another. Electromagnetic signals may travel from one sender to another through a vacuum, air, or other transmission media. This blog aims to provide you with an overview of the transmission media in computer networks and types of transmission media.

What is Transmission Media in Computer Networks?

Transmission Media is a method of establishing a communication medium to transmit and receive information in the form of electromagnetic signal waves. Since different physical components operate it, it is put under the physical layer while being worked on by physical elements from the physical layer. A LAN, or local area network, is the physical setup where a transmitter and receiver communicate utilizing a Transmission medium. Copper-based or fiber-based transmission media are used to carry either electric or optical signals. The transmission medium is also known as a communication channel.

Copper-based or fibre-based transmission media are used to carry either electric or optical signals. The transmission medium is also known as a communication channel.
The transmission media is mainly of two types: Wired Media and Wireless Media through which data is transmitted. To measure the quality of data that is transmitted, and its characteristics can be calculated by the characteristics of medium and signal.
In wired media, the characteristics of the medium are more important and on the other hand in wireless media, the characteristic of the signal are much more vital.
There are several Transmission Media and all of them have different properties which includes bandwidth, delay, cost and ease of installation and maintenance. And depending on these factors Transmission media is selected for the data transfer.

Media Terminology
1. Segment length – The signal degrades for each type of media after traveling a certain distance to the point where it becomes unintelligible. This distance is referred to as the segment length.
2. Attenuation – The loss of signal strength when traveling a distance is called attenuation. Measured in decibels (DB).
3. Bandwidth – Amount of data that can travel through the cable in a unit period of time. Measure in kbps, Mbps, etc.
4. Interference – Each cable is susceptible to certain forms of external noise. This is called EMI (Electromagnetic Interference) or RFI (Radio frequency interference)
5. Crosstalk – When a signal carrying conductor is placed near another signal carrying conductor. Interference is generated in the other cable. This is called crosstalk.

Now, that we have a good knowledge of Transmission Media, it is time to indulge ourselves to the types of Transmission Media.

Types of Transmission Media
Depending on the nature and quality of the transmission, the following types of transmission media may be broken down into two categories: Guided and Unguided Transmission Media.

Guided or Wired Transmission Media

This type of media uses cables to transmit signals across the network. Wired media, often known as guided media, is a form of transmission medium. It has a finite range in the communication system and is also known as a Bounded transmission media. With the use of physical wiring connections, the qualities of the transmission signals may be concentrated and contained inside a specific, constrained channel. Transmission speeds are one of the most striking features of this kind of communication.

The Guided Transmission media is of three types, which are:

Coaxial Cable
Twisted-Pair Cable
Fiber-optic Cable

Let’s see each type in detail.

1. Coaxial

The core is made up of copper conductors. Its purpose is the signal transmission. To prevent the copper conductor from overheating, an insulator is utilized. A metal conductor is braided around the insulator. It aids in blocking out any unwanted noise or allowing for any unwanted cross-talk between electrical signals. The setup is entirely covered in a protective plastic layer.

Its Features –

Protection from crosstalk/ EMI/ RFI
Difficult to install
Expensive
Usually used in broadcast medium ex: Cable TV
Segment length of 200m to 500m

Advantages of Coaxial Cable

It is easier to install.
It has better shielding.
It is capable of transmitting data over longer distances.
Coaxial cables are less affected by noise or cross-talk.

Disadvantages of Coaxial Cable

Coaxial cables are more expensive than others.
They are less flexible and bulkier.
They must be grounded in order to avoid crosstalk.

2. Twisted Pair

This cable has eight insulated wires. These are paired in groups of 2 and are twisted together based on a color code. The twisting is done to decrease interference caused by the adjacent wires. One wire in the pair may send signals to the receiver, while the other serves as a ground reference. The twisted pair is further divided into two parts, i.e., shielded and unshielded.

a. Shielded twisted pair

These twisted pair cables are covered in a braided shield which acts as a shield from outside interference.

Protection from crosstalk/ RFI/ EMI
More expensive than UTP
Difficult to install
Segment length of up to 100m

Ethernet Type	Bandwidth	Cable Type	Maximum Distance
10Base-T	10Mbps	Cat 3/Cat 5 UTP	100m
100Base-TX	100Mbps	Cat 5 UTP	100m
100Base-TX	200Mbps	Cat 5 UTP	100m
100Base-FX	100Mbps	Multi-mode Fiber	400m
100Base- FX	200Mbps	Multi-mode Fiber	2Km
1000Base-T	1Gbps	Cat 5e UTP	100m
1000Base-TX	1Gbps	Cat 6 UTP	100m
1000Base-SX	1Gbps	Multi-mode Fiber	550m
1000Base-LX	1Gbps	Single-mode Fiber	2Km
10GBase-T	10Gbps	Cat 6a/Cat 7 UTP	100m
10GBase-LX	10Gbps	Multi-mode Fiber	100m
10GBase-LX	10Gbps	Single-mode Fiber	10Km

Advantages of Shielded Twisted Pair

Shielded Twisted Pair is capable of eliminating crosstalk.
It is faster compared to Unshielded Twisted pair.

Disadvantages of Shielded Twisted Pair

It is more expensive.
It is more bulky.
It is difficult to manufacture and install.

b. Unshielded twisted pair

These twisted pair cables do not have a braided shield. The 4 pairs are simply covered in a plastic insulator for safety.

Prone to crosstalk/ RFI/ EMI
Inexpensive
Most common
Easy to install
Segment length of up to 100m

Color Codes –

Straight through cable

When the same color codes are used at both ends. For ex, 568A on both ends. Alternatively, 568B on both ends
Used when connecting different types of devices, for ex, connecting a PC to a switch, or a switch to a router

Crossover cable

When different color codes are used at both ends. For ex, one end is 568A, and the other end is 568B
Used when connecting similar types of devices. For ex, A PC to a PC or a switch to a switch, etc.

Advantages of Unshielded Twisted Pair

Less expensive.
It is easy to install.

Disadvantages of Unshielded Twisted Pair

Lower capacity.
Not suitable for long distance transmission.

3. Fiber Optics Cable

In addition, optical fiber, a physical medium, has also become the standard for long-distance communications. Optical fibers are transparent, flexible wires composed of glass (silica) or plastic that are just a little thicker than a human hair. It acts as a waveguide, allowing light to travel between the fiber’s two ends.

Fiber optic communications rely heavily on optical fibers because they allow for greater bandwidths (data rates) and transmission over greater distances than traditional modes of communication. It contains strands of glass fibers inside an insulated casing. The route for light is provided by the core, located in the center. The core is surrounded by cladding that reflects light to prevent loss of signal and allow the passage of light.

Single mode

Single strand of glass fiber
Single data signal
Can span large distances
Uses laser
Transmission speeds are faster
Long Distance Data Transmisson up To 80KM

2. Multi-mode

Can carry multiple modes of the data signal
Can carry multiple light signals
Can span lesser distances than single mode
Uses LED
Transmission speeds are lower than single mode
Short Distance Data Transmisson up To 2KM

Advantages of Fiber Optics Cable

Here are some advantages of fibre optics:

Extremely High-speed data transmission.
It is capable of long distance transmission without signal disruption.
It is immune to electromagnetic intervention.

Disadvantages of Fiber Optics Cable

Here are some disadvantages:

It is very expensive to install and maintain.
It is very fragile in nature and need special handling.

Unguided or Wireless Transmission Media

Unguided media, also termed as unbound transmission medium, is a method of transmitting data without the need for cables. Physical geography has no bearing on these media. Unguided media are also known as wireless communication. It is a wireless transmission media channel that does not need a physical medium to connect to network nodes or servers.

There are three types of unguided Transmission Media, that are:

Radio Waves
Microwave
Infrared

Let’s understand each in detail.

1. Radio Waves Transmission

Radio waves are a type of non-ionizing electromagnetic radiation used for wireless communication. Let’s understand in detail.

Frequency Range

Radio waves have a frequency range of 3 kHz to 300 GHz.
It is important to note that lower-frequency radio waves are mainly used for AM radio broadcasting. On the other hand, higher frequency radio waves are used for FM radio broadcasting as well as for satellite communications.

Direction of Communication

Radio waves can be directional, which means that the waves are focused in a specific direction. Also, radio waves can be omnidirectional, i.e., propagated in all directions.

Role of Antenna

An antenna is a crucial component of radio wave transmission, which is responsible for converting electrical energy into radio waves.

The antenna’s shape, size, and orientation affect the direction and strength of the radio waves.

Application

Radio broadcasting
Mobile communication
Wireless networking
Radar and navigation

Advantages of Radio Waves

Long-distance Communication
Portable
Reliable Communication
Easy Installation

Disadvantages of Radio Waves

Prone to Interference
Atmospheric Disturbances
Limited Bandwidth
Health Risks

2. Microwave Transmission

Microwave transmission is a method of transmitting data through high-frequency electromagnetic waves over long distances. Let’s understand in detail.

Frequency Range

Microwaves generally operate at a frequency range of 1GHz to 300 GHz.
It is important to note that the most common frequency range is between 3GHz to 30 GHz.

Direction of Communication

Microwaves are line-of-sight (LOS) communications. It simply means that the transmitting and receiving antennas must be in direct sight of each other.
Microwaves are Unidirectional.

Role of Antenna

The antenna plays a crucial role in microwave transmission, as it converts electrical signals into microwave energy and transmits them through the air.

Types of Microwave Transmission

There are two types of microwave transmission. These are:

Terrestrial Microwaves: These microwaves are used for communication purposes, especially between two points on the Earth’s surface. One such example is the communication between two towers or buildings.

Satellite Microwaves: These microwaves are used for communication between the Earth and a satellite in orbit. It is crucial for global communication and broadcasting.

Applications of Microwave Transmission

Wireless local area networks (WLANs)
Satellite communications
Radar systems
Wireless broadband internet
Point-to-point communication links
Radio astronomy
Military communications
Weather radar systems

Advantages of Microwave Transmission

High-speed data transfer
Easy to install and set up
Cost-effective solutions
Reliable communication with minimal downtime
Fast deployment

Disadvantages of Microwave Transmission

Interrupted by physical obstacles
Obstructions in the line of sight can affect signal quality
Security risks
Limited range
Atmospheric conditions can impact microwave signal quality

3. Infrared

Infrared waves are a type of energy that can travel through the air. Let’s discuss Infrared waves in detail.

Frequency Range – The frequency range is between 300GHz and 400 THz. This simply means that they can travel a certain distance and then fade away.

Communication Range – In general, Infrared waves are used to send information between devices that are close to each other. This is known as short-range communication.

How it works?

In order to send information with Infrared waves, we need special devices known as transceivers. These devices can send as well as receive infrared light. For infrared communication to work, it is recommended that the two devices that need to communicate with one another should be in sight of each other. In simple words, they need to be facing each other. If not, the light can bounce off a light-colored surface like a ceiling or a wall in order to reach the other device.

Applications

Wireless Keyboards and Mouse
TV Remote Control
Night Vision
Weapon System

Advantages of Infrared

Secure and high-speed data transfer
Low Power Consumption
Relatively directional
Easy to Build into Devices

Disadvantages of Infrared

Line of Sight Requirement
Limited Range
High Attenuation

That’s all from the Wireless Transmission Media.

Comparison of Various Transmission Media

Here we have compared various types of transmission media:

Transmission Media	Speed	Distance	Interference Resistance	Cost	Best Use Cases
Twisted Pair Cable	Up to 10 Gbps	100 Meter	Moderate	Low	LAN, Telephone Lines
Coaxial Cable	Up to 10 Gbps	Several KM	High	Medium	Cable TV, Broadband
Fiber Optic Cable	Up to Tbps	Several KM	Very High	High	High-speed Internet
Radio Waves	Up to Gbps	Several KM	Low	Medium	Wi-Fi, Mobile Networks
Microwaves	Up to Gbps	100+ KM	Medium	High	Satellite, TV Broadcasting
Infrared	Mbps	Few Meters	Very High	Low	Remote Controls, Bluetooth

How to choose the right Transmission Media?

For Effective communication, it is crucial to choose the right transmission media. Let us discuss some of the factors that need to be considered.

Distance: It simply means the distance the signal needs to travel. For short distances, twisted pair or fiber optic cables may be suitable. For longer distances, coaxial cables or satellite transmission is suitable.
Bandwidth: It means the amount of data to be transmitted. Low-bandwidth applications such as voice calls can use twisted pair cables. At the same time, high-bandwidth applications such as video streaming require fibre optics or coaxial cables.
Cost: It is crucial to consider the cost factor while choosing the transmission media. If someone wants to go for a cheaper option, twisted pair cables are the best option to go.
Security: It is always good to secure your network in order to protect sensitive information as well as resources. For example, fiber optic cables are often used for high-security applications.

Comparing Guided and Unguided Transmission Media

Factor	Guided Media	Unguided Media
Transmission Medium	Physical Cables (Copper, Fiber Optics)	Air, Space
Cost	Lower for low disances	Very High
Distance	Short to medium	Long
Interference	Very low	High interference
Speed	High, especially with Fiber Optics Cable	Varies from low to high depending on the technology
Flexibility	Very less flexible due to fixed infrastructure	Highly Flexible

Frequently Asked Questions

Q1. What is the transmission media?

Transmission Media carries the information through LAN in the form of bits. It mainly carries information between the sender and the receiver therefore known as communication channels. Examples include twisted pair cables, coaxial cables, fiber optic cables, wireless technologies (like Wi-Fi and Bluetooth), microwave transmission, and satellite communication. The choice of transmission media depends on factors like distance, bandwidth requirements, and susceptibility to interference.

Q2. What are 4 types of transmission media?

Here are the 4 types of transmission media – Twisted Pair, Coaxial Cable, Fiber Optic Cable, and Wireless Transmission.

Q3. What is guided and unguided media?

Guided media refers to transmission media that provide a physical path or conductor for transmitting signals. It includes media like twisted pair cables, coaxial cables, and fiber optic cables, where the signals are guided along the transmission path.

Unguided media, on the other hand, refers to transmission media that do not provide a physical path for signal transmission. Instead, the signals are propagated through the air or space using wireless technologies such as radio waves, microwaves, and satellite communication. Unguided media do not rely on a physical medium to transmit signals and are sometimes referred to as wireless or free space communication.

Q4. What are the types of unguided media?

Here are a the types of unguided media – Radio Waves, Microwaves, Infrared, Light Waves, and Satellite Communication.

Networking Cables

here are several types of networking cables, each designed for specific uses and environments. Here’s a breakdown of the most common types:
1. Ethernet Cables (Twisted Pair Cables)
- Cat5 (Category 5):
  - Older standard, supports speeds up to 100 Mbps over distances of up to 100 meters.
- Cat5e (Category 5 Enhanced):
  - Improved version of Cat5, supports speeds up to 1 Gbps and reduces crosstalk, still over 100 meters.
- Cat6 (Category 6):
  - Supports speeds up to 10 Gbps, typically up to 55 meters, with improved shielding to reduce interference.
- Cat6a (Category 6 Augmented):
  - Improved version of Cat6, supports 10 Gbps over longer distances (up to 100 meters).
- Cat7 (Category 7):
  - Supports speeds up to 10 Gbps, with higher shielding for reduced interference and crosstalk, often used in data centers or high-performance environments.
- Cat8 (Category 8):
  - Supports speeds up to 25-40 Gbps, but only for shorter distances (up to 30 meters), used mainly in data centers.
2. Coaxial Cable
- RG-6:
  - Commonly used for cable TV and broadband internet connections.
- RG-59:
  - Used for lower-frequency applications like CCTV or older TV installations.
3. Fiber Optic Cables
- Single-mode Fiber (SMF):
  - Used for long-distance communication, with a single light path, supporting faster speeds and longer ranges (up to tens of kilometers).
- Multi-mode Fiber (MMF):
  - Used for shorter distances, with multiple light paths, suitable for local area networks (LANs) and data centers.
4. USB Cables (for Networking in Some Cases)
- USB 3.0 / USB 3.1:
  - Can be used for direct connections between devices like computers, routers, and networked storage (e.g., NAS).
5. Power over Ethernet (PoE) Cables
- Standard Ethernet cables (Cat5e, Cat6) can also carry electrical power, not just data, to devices like IP cameras, VoIP phones, and wireless access points.
6. Serial Cables
- Typically used for specific networking applications such as console management (e.g., connecting a computer to a router/switch for configuration).
Each cable type has its advantages and is chosen based on the specific requirements of the network—such as distance, speed, and environmental factors.

Networking Cable Details

Here’s a detailed comparison of Cat5, Cat5e, Cat6, Cat6a, and Cat7 cables, which are all types of Ethernet cables used in networking.

1. Cat5 (Category 5) Cable

Standard: The original Ethernet standard for networking.
Speed: Supports speeds up to 100 Mbps.
Bandwidth: Up to 100 MHz.
Max Length: Maximum transmission distance of 100 meters (328 feet).
Use Case: Primarily used for 10/100 Mbps Ethernet networks. It’s now considered outdated and generally not recommended for modern networks.
Shielding: No shielding (UTP – Unshielded Twisted Pair).
Availability: Being phased out in favor of higher-performance cables like Cat5e and Cat6.

2. Cat5e (Category 5 Enhanced) Cable

Standard: An enhanced version of Cat5, designed to reduce crosstalk and electromagnetic interference (EMI).
Speed: Supports speeds up to 1 Gbps (Gigabit Ethernet).
Bandwidth: Up to 100 MHz.
Max Length: Maximum transmission distance of 100 meters (328 feet) at 1 Gbps.
Use Case: Ideal for home and small office networks. Still widely used for Gigabit Ethernet networks.
Shielding: Typically unshielded (UTP) but can be shielded (STP or FTP) for environments with higher interference.
Availability: Common in most networking environments due to its cost-effectiveness and performance for general-purpose use.

3. Cat6 (Category 6) Cable

Standard: A higher-performance cable, often used for more demanding network setups.
Speed: Supports speeds up to 10 Gbps over short distances (up to 55 meters or 180 feet).
Bandwidth: Up to 250 MHz.
Max Length: Maximum transmission distance of 100 meters (328 feet) at lower speeds (1 Gbps), and 55 meters (180 feet) at 10 Gbps.
Use Case: Used in businesses, data centers, and high-speed internet installations where Gigabit Ethernet or higher is required.
Shielding: Usually unshielded (UTP), but can come in shielded variants (STP, FTP).
Availability: Common for new installations, especially when 10 Gbps speeds are needed.

4. Cat6a (Category 6 Augmented) Cable

Standard: An augmented version of Cat6 that supports higher speeds and better performance at longer distances.
Speed: Supports speeds up to 10 Gbps over the full 100-meter length.
Bandwidth: Up to 500 MHz.
Max Length: Maximum transmission distance of 100 meters (328 feet) at 10 Gbps.
Use Case: Common in enterprise environments, data centers, and situations requiring consistent 10 Gbps performance over longer distances.
Shielding: Often comes with shielding (STP or FTP) to reduce crosstalk and external interference.
Availability: Becoming increasingly popular in networks where future-proofing is important (higher speeds, longer distances).

5. Cat7 (Category 7) Cable

Standard: Designed for high-speed networks and environments with substantial electromagnetic interference.
Speed: Supports speeds up to 10 Gbps.
Bandwidth: Up to 600 MHz.
Max Length: Maximum transmission distance of 100 meters (328 feet) at 10 Gbps.
Use Case: Used in high-performance environments, including large data centers, server farms, or areas with high EMI (electromagnetic interference).
Shielding: Fully shielded (STP – Shielded Twisted Pair) with individual shielding around each pair of wires, as well as an overall shield. This helps reduce crosstalk and external interference.
Availability: Less common for general consumer use due to its cost and over-engineering for typical home or office networks. However, it’s beneficial for environments with significant electrical noise or very high-speed requirements.

Summary Table

Category	Speed	Bandwidth	Max Length (100% Performance)	Common Use	Shielding
Cat5	100 Mbps	100 MHz	100 meters	Older networks, now obsolete	Unshielded (UTP)
Cat5e	1 Gbps	100 MHz	100 meters	Home networks, small offices	Unshielded (UTP)
Cat6	10 Gbps (short)	250 MHz	55 meters (10 Gbps) / 100 meters (1 Gbps)	Business, Gigabit and 10-Gigabit Ethernet networks	Unshielded (UTP), Shielded (STP/FTP)
Cat6a	10 Gbps	500 MHz	100 meters	Data centers, enterprise networks, high-speed setups	Shielded (STP/FTP)
Cat7	10 Gbps	600 MHz	100 meters	High-performance environments, high EMI areas	Fully shielded (STP)

Key Differences Between Cat5e, Cat6, and Cat7:

Speed: Cat5e supports up to 1 Gbps, Cat6 supports up to 10 Gbps (but only for short distances), and Cat7 supports 10 Gbps over long distances.
Bandwidth: Cat6 and Cat7 have higher bandwidths (250 MHz and 600 MHz, respectively) compared to Cat5e (100 MHz).
Shielding: Cat5e is unshielded, while Cat6 and Cat7 often have shielding (especially Cat6a and Cat7), providing protection against interference and ensuring better performance in noisy environments.
Distance: All cables support 100 meters for 1 Gbps, but for higher speeds (10 Gbps), Cat6 is limited to 55 meters, while Cat6a and Cat7 maintain 10 Gbps over the full 100 meters.

Conclusion:

Cat5e is still a popular choice for most home and office networks, especially where gigabit speeds are sufficient.
Cat6 and Cat6a are ideal for medium to large businesses or homes that require higher speeds, like 10 Gbps.
Cat7 is the most robust and shielded option, suited for high-performance, low-interference environments, but it’s usually overkill for typical residential or small office use.

Each type of cable provides a different level of performance depending on the needs of your network, with Cat5e being the most common and cost-effective option, while Cat7 is designed for environments where superior performance is necessary.

D-Link CAT6 305M Armored Outdoor Use 23AWG Copper Cable

D-Link CAT6 UTP Pure Copper 100mtrs Cable Indoor Use

Fiber Optical Cable Details

Fiber optic cables are categorized based on their construction and how they transmit light signals. The two main types of fiber optic cables are single-mode fiber (SMF) and multi-mode fiber (MMF). Within these categories, there are variations depending on the performance requirements, the number of cores, and the applications they support.

Here’s a breakdown of the different types of fiber optic cables:

1. Single-Mode Fiber (SMF)

Core Size: Small core diameter, typically 8 to 10 microns.
Light Transmission: Uses a single light path (laser or LED) to transmit data.
Bandwidth: High bandwidth and low attenuation (signal loss) over long distances.
Max Distance: Supports longer transmission distances, from several kilometers to tens of kilometers (up to 40 km or more).
Applications: Ideal for long-distance data transmission, such as telecommunications, internet backbones, data centers, and networking between cities.
Advantages:
- Long-range communication without significant signal degradation.
- Higher data rates (up to 100 Gbps or more).
- Low dispersion and loss over long distances.
Disadvantages:
- More expensive than multi-mode fiber.
- Requires more precise installation and alignment.

2. Multi-Mode Fiber (MMF)

Core Size: Larger core diameter, typically 50 microns or 62.5 microns.
Light Transmission: Uses multiple light paths or modes, typically transmitted by an LED light source.
Bandwidth: Supports lower bandwidth and shorter distances than SMF.
Max Distance: Typically used for distances up to 2 km (1.24 miles) at 1 Gbps, but can handle shorter distances for higher speeds (e.g., 10 Gbps over 300 meters).
Applications: Suitable for local area networks (LANs), data centers, enterprise networking, and shorter distance communications (within buildings or campuses).
Advantages:
- Less expensive than single-mode fiber.
- Easier to handle and install.
Disadvantages:
- Shorter transmission distances due to higher attenuation and modal dispersion.
- Lower data transfer rates over longer distances.

3. Types of Multi-Mode Fiber

There are different grades or “types” of multi-mode fiber, based on core size and performance:

OM1 (Optical Multi-mode 1):
- Core Size: 62.5 microns.
- Bandwidth: Up to 200 MHz·km at 850 nm.
- Max Distance: Supports up to 275 meters at 1 Gbps, and around 33 meters at 10 Gbps.
- Use: Older fiber type, now mostly phased out but still found in legacy systems.
OM2 (Optical Multi-mode 2):
- Core Size: 50 microns.
- Bandwidth: Up to 500 MHz·km at 850 nm.
- Max Distance: Supports up to 550 meters at 1 Gbps, and around 82 meters at 10 Gbps.
- Use: Suitable for 1 Gbps applications, but less efficient at higher speeds.
OM3 (Optical Multi-mode 3):
- Core Size: 50 microns.
- Bandwidth: Up to 2000 MHz·km at 850 nm.
- Max Distance: Supports up to 300 meters at 10 Gbps, and 100 meters at 40 Gbps.
- Use: Designed for higher-speed applications, including 10 Gbps and 40 Gbps transmission.
OM4 (Optical Multi-mode 4):
- Core Size: 50 microns.
- Bandwidth: Up to 4700 MHz·km at 850 nm.
- Max Distance: Supports up to 400 meters at 10 Gbps, and up to 150 meters at 100 Gbps.
- Use: High-performance fiber for data centers and high-speed enterprise networks, optimized for higher data rates and longer distances.
OM5 (Optical Multi-mode 5):
- Core Size: 50 microns.
- Bandwidth: Up to 20000 MHz·km at 850 nm (supports wideband transmission).
- Max Distance: Supports 40 Gbps over 150 meters and 100 Gbps over 100 meters.
- Use: A more recent addition for supporting short-wavelength division multiplexing (SWDM), used in high-performance, future-proof networks.

4. Armored Fiber Optic Cable

Description: Fiber optic cables with an additional protective layer (typically steel or aluminum) to prevent physical damage.
Applications: Used in environments where cables are exposed to harsh conditions or are at risk of being damaged, such as outdoor installations or industrial settings.
Advantages:
- Provides physical protection against impacts, rodents, and crushing forces.
- Can be used in underground, outdoor, or heavy-duty installations.

5. Aerial Fiber Optic Cable

Description: Fiber optic cables designed for overhead installations, usually suspended between utility poles.
Applications: Used for telecommunication services in rural or suburban areas where underground cabling is not feasible.
Advantages:
- Cost-effective for long-distance outdoor installations.
- Can be easily installed and maintained.

6. Loose Tube Fiber Optic Cable

Description: Fiber cables where the fibers are enclosed in a loose tube filled with gel or water-blocking material to protect against moisture and temperature extremes.
Applications: Suitable for outdoor and underground applications, especially in environments where water or temperature variations can affect performance.
Advantages:
- Offers more protection against environmental factors like moisture and temperature changes.

7. Tight-Buffered Fiber Optic Cable

Description: Fiber optic cables where each fiber is coated with a protective buffer layer (often a plastic coating), making them more rugged.
Applications: Primarily used for indoor installations, such as inside buildings, data centers, and structured cabling systems.
Advantages:
- More flexible than loose-tube cables.
- Easier to handle for indoor applications.

Fiber Cable Construction Types:

Simplex Cable: Single fiber inside the cable. Typically used for one-way communication.
Duplex Cable: Two fibers, often used for bidirectional data transmission.
Ribbon Cable: A type of fiber optic cable where multiple fibers are arranged side by side in a flat ribbon-like formation. It allows for high-density installations, ideal for data centers.

Summary Table of Fiber Optic Cable Types

Fiber Type	Core Diameter	Transmission Method	Max Distance	Max Bandwidth	Applications
Single-Mode (SMF)	8-10 microns	Laser (1 light path)	Long distance (up to 40 km or more)	High (e.g., 100 Gbps)	Long-distance communication, telecommunications
Multi-Mode (MMF)	50 or 62.5 microns	LED (multiple light paths)	Short distance (up to 2 km)	Lower (e.g., 1-10 Gbps)	LANs, data centers, enterprise networks
OM1	62.5 microns	LED	275 meters (1 Gbps), 33 meters (10 Gbps)	200 MHz·km	Legacy networks, low-speed applications
OM2	50 microns	LED	550 meters (1 Gbps), 82 meters (10 Gbps)	500 MHz·km	Mid-range speed networks, general use
OM3	50 microns	LED	300 meters (10 Gbps), 100 meters (40 Gbps)	2000 MHz·km	High-speed data centers, enterprise networks
OM4	50 microns	LED	400 meters (10 Gbps), 150 meters (100 Gbps)	4700 MHz·km	High-speed, high-performance applications
OM5	50 microns	LED	150 meters (40 Gbps), 100 meters (100 Gbps)	20000 MHz·km	Future-proof, high-performance networks

Conclusion:

Single-mode fiber is optimal for long-distance, high-speed connections, and is often used in backbone networks or telecommunications.
Multi-mode fiber is more affordable and typically used for shorter distances, such as within data centers, local area networks (LANs), and enterprise environments.
Fiber optic cables are also available in different configurations, like armored, aerial, and loose tube, to address specific

Crimping RJ45

Crimping an RJ45 connector involves attaching an Ethernet cable to an RJ45 plug so it can be used in networking applications. Below is a step-by-step guide on how to crimp an RJ45 connector properly.

Materials Needed:

Ethernet Cable (Cat5e, Cat6, or higher, depending on your need)
RJ45 Connectors (These come in both 8P8C and 8P8C Shielded types, but the 8P8C is the most common)
Crimping Tool (A crimper with a cutting and stripping function)
Cable Stripper (If not included with your crimping tool)

Steps to Crimp an RJ45 Connector:

Prepare the Cable:
- Strip the Cable Jacket: Use the cable stripper to remove about 1-2 inches of the outer jacket of the Ethernet cable. Be careful not to cut into the wires inside.
- Untwist the Pairs: Ethernet cables are made up of 4 twisted pairs of wire (8 total wires). Untwist the pairs carefully so that each individual wire is separated.
Arrange the Wires:
- There are two standard wiring schemes for Ethernet cables: T568A and T568B. The wiring order is slightly different depending on which standard you use.
T568A Wiring (often used in residential settings):
- Pin 1: White/Green
- Pin 2: Green
- Pin 3: White/Orange
- Pin 4: Blue
- Pin 5: White/Blue
- Pin 6: Orange
- Pin 7: White/Brown
- Pin 8: Brown
T568B Wiring (often used in commercial and networking environments):
- Pin 1: White/Orange
- Pin 2: Orange
- Pin 3: White/Green
- Pin 4: Blue
- Pin 5: White/Blue
- Pin 6: Green
- Pin 7: White/Brown
- Pin 8: Brown
Note: Make sure you are consistent with the wiring standard on both ends of the cable if you are creating a straight-through cable.
Trim the Wires:
- After arranging the wires in the correct order, trim them evenly so that they are all the same length (about 1/2 inch from the end of the cable jacket).
Insert the Wires into the RJ45 Connector:
- Hold the RJ45 connector with the clip facing you, and carefully insert the wires into the connector. Make sure each wire goes all the way to the front of the connector, and that the wires are in the correct order.
- The copper part of each wire should make contact with the metal pins inside the RJ45 connector.
Crimp the Connector:
- Insert the RJ45 connector into the crimping tool’s slot.
- Squeeze the crimping tool firmly to press the metal pins into the wires. This creates a solid connection between the wires and the connector.
- If the crimping tool has a cutting function, it will also trim any excess wire length at this point.
Test the Cable:
- It’s a good idea to test the cable using a cable tester to ensure that all the connections are correct and working properly.
- If you don’t have a cable tester, you can check by plugging the cable into a device like a router and a computer to see if the network connection works as expected.

Additional Tips:

Quality: Use high-quality connectors and cables for better signal integrity, especially if you are creating longer cables or using high-speed networking (like gigabit Ethernet).
Correct Tools: A proper crimping tool makes a huge difference. A cheap crimper may not seat the pins properly, causing connectivity issues.