Binary Code and Computers - Bandwithmonitors on binary code floor

What is network bandwidth?

Network bandwidth is a measurement indicating the maximum capacity of a wired or wireless communications link to transmit data over a network connection in a given amount of time. Typically, bandwidth is represented in the number of bits, kilobits, megabits, or gigabits that can be transmitted in 1 second. Synonymous with capacity, bandwidth describes the data transfer rate. Bandwidth is not a measure of network speed—a common misconception.

How does bandwidth work?

The more bandwidth a data connection has, the more data it can send and receive at one time. In concept, bandwidth can be compared to the volume of water flowing through a pipe. The wider the pipe’s diameter, the more water can flow through it at one time. Bandwidth works on the same principle. The higher the communication link capacity, the more data can flow through it per second.

The cost of a network connection goes up as bandwidth increases. Thus, a 1 gigabit per second (Gbps) Dedicated Internet Access (DIA) link will be more expensive than one that can handle 250 megabits per second (Mbps) of throughput.

Bandwith Requirements

How to measure bandwidth

While bandwidth is traditionally expressed in bits per second (bps), modern network links have far greater capacity, often described as Mbps or Gbps.

Bandwidth connections can be symmetrical, which means the data capacity is the same in both directions—upload and download—or asymmetrical, which means download and upload capacity are not equal. In asymmetrical connections, upload capacity is typically smaller than download capacity; this is common in consumer-grade internet broadband connections. Enterprise-grade WAN and DIA links more commonly have symmetrical bandwidth.

Considerations for calculating bandwidth

Technology advances have made some bandwidth calculations more complex, and they can depend on the type of network link being used. For example, optical fiber using different kinds of light waves and time-division multiplexing can transmit more data through a connection simultaneously compared to copper Ethernet alternatives, which effectively increases its bandwidth.

In mobile data networks, such as Long-Term Evolution, or LTE, and 5G, bandwidth is defined as the spectrum of frequencies that operators can license from the Federal Communications Commission and the National Telecommunications and Information Administration for use in the U.S. This spectrum cannot be legally used by anyone other than the business that owns the license to it. The carrier can then use wireless technologies to transport data across that spectrum to achieve the most excellent bandwidth the hardware can provide.

Wi-Fi spectrum, on the other hand, is considered to be unlicensed. Thus, anyone with a Wi-Fi access point (AP) or Wi-Fi router can create a wireless network. The caveat is that the spectrum is not guaranteed to be available. Thus, Wi-Fi bandwidth can suffer when other Wi-Fi APs attempt to use some or all of the same frequencies.

Adequate bandwidth- the highest reliable transmission rate a link can provide on any given transport technology- can be measured using a bandwidth test. During a bandwidth test, the link’s capacity is determined by repeatedly measuring the time required for a specific file to leave its point of origin and successfully download at its destination.

After determining bandwidth consumption across the network, it is necessary to see where applications and data reside and calculate their average bandwidth needs for each user and session.

To understand how much bandwidth a network uplink or internet broadband requires, follow these four steps:

  1. Determine which applications will be in use.
  2. Determine the bandwidth requirements of each application.
  3. Multiply the application requirements of each application by the number of expected simultaneous users.
  4. Add all application bandwidth numbers together.

The same calculation applies to determine bandwidth needs for public or private clouds across internet or WAN links. However, the difference is that available bandwidth on a local area network or wireless LAN is typically far more significant than WAN or DIA connections. Thus, accurately assessing bandwidth requirements is critical, as is monitoring link utilization over time. Tracking the bandwidth used throughout the day, week, month, or year can help network engineers determine whether a WAN/DIA link has sufficient bandwidth — or if a bandwidth upgrade is needed.

When there is insufficient bandwidth on a network, applications and services perform poorly.

Factors affecting network performance

The maximum capacity of a network connection is only one factor that affects network performance. Packet loss, latency, and jitter can degrade network throughput and make a high-capacity link perform like one with less available bandwidth.

An end-to-end network path usually consists of multiple connections with different bandwidth capacity. As a result, the link with the lowest bandwidth is often described as the bottleneck because it can limit the overall capacity of all connections in the path.

Many enterprise-grade networks are deployed with multiple aggregated links acting as a single logical connection. If, for example, a switch uplink uses four aggregated 1 Gbps connections, it has an adequate throughput capacity of 4 Gbps. However, if two of those links were to fail, the bandwidth limit would drop to 2 Gbps.

Bandwidth on demand

Bandwidth for internet or WAN links is typically sold at a set monthly price. However, bandwidth on demand- dynamic bandwidth allocation or burstable bandwidth- is an alternative model that enables subscribers to increase the amount of available bandwidth at specific times or for particular purposes. Bandwidth on demand is a technique that can provide additional capacity on a communications link to accommodate bursts in data traffic that temporarily require more bandwidth.

Rather than overprovisioning the network with expensive dedicated links year-round, bandwidth on demand is frequently used in WANs to increase capacity for a special event or time when traffic is expected to spike. An online flower retailer, for example, may only need to increase its capacity in the weeks leading up to Mother’s Day. Bandwidth on demand enables enterprises to only pay for the additional bandwidth they consume over a shorter period.

Bandwidth on demand is available through many internet and WAN service providers. Depending on a customer’s network link, a provider may be able to provision additional capacity on demand using the existing connection. For example, a 100 Mbps link might be able to burst up to 1 GB because the service provider’s connection has available capacity. If a customer needed more than the maximum bandwidth available on that link, another physical connection would be required.

Occasionally, a service provider will enable customers to burst above their subscribed bandwidth cap without charging additional fees. However, if customers sustain more than 100 Mbps using the burst feature regularly, the service provider commonly bills them using 95th percentile calculations.

SD-WAN eases dedicated bandwidth capacity planning processes

Software-defined WAN (SD-WAN) technology can provide customers extra capacity by balancing traffic across multiple WAN and DIA connections rather than a single connection. SD-WAN deployments often use a Multiprotocol Label Switching, or MPLS, connection or other types of dedicated transport links in combination with a lower-cost broadband internet or cellular connection.

How do you optimize and monitor bandwidth use?

Network engineers have several options available when a network link becomes congested. The most frequent choice is to increase bandwidth. This can be achieved by upgrading the link’s physical throughput capabilities or through port aggregation and load balancing to split traffic across multiple links logically. However, sometimes, these techniques are not possible.

ISPs or network administrators may also intentionally adjust the speed — up or down — of data traveling over the network, a measure known as bandwidth throttling. There are different reasons for bandwidth throttling, including limiting network congestion, particularly on public access networks. ISPs may use throttling to reduce bandwidth use by a particular user or class of users. For example, with tiered pricing, a service provider can offer a menu of upload and download bandwidth. ISPs can also throttle bandwidth to even out usage across all users on the network.

The internet’s bandwidth throttling has been criticized by net neutrality advocates, who say that the practice can be misused for political or economic reasons and unfairly targets segments of the population.

A speed test can be run to see if an ISP is throttling bandwidth. Speed tests measure the speed between a device and a test server using a device’s internet connection. ISPs offer speed tests on their websites, and independent tests are also available from services such as Speedtest. Because many factors can affect the results of a speed test, it is generally recommended to perform multiple tests at different times of the day and engage different servers available through the speed test site. A speed test over a wired connection is also recommended.

Data transfer throttling intentionally restricts the amount of data sent or received over a network to prevent spam or bulk email transmission through a server. It can be considered another form of bandwidth throttling. If implemented on a large enough scale, data transfer throttling can control the spread of computer viruses, worms, or other malware through the Internet.

Network bandwidth monitoring tools are available to help identify performance issues, such as a faulty router or a malware-infected computer participating in a distributed denial-of-service attack. As noted earlier, bandwidth monitoring can also help network administrators better plan for future network growth — seeing where in the network bandwidth is most needed. Monitoring tools can also help administrators see if their ISP is fulfilling the service-level agreement in their contract.


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