The Central Processing Unit (CPU) is the brain of a computer. It is responsible for executing instructions and controlling the operation of the computer. Without a CPU, a computer would be unable to perform any tasks. In this article, we will explore the basics of CPU and answer the question, “What does CPU stand for?” We will also delve into the history of CPU and how it has evolved over time. Whether you are a seasoned programmer or a curious beginner, this article will provide you with a comprehensive understanding of the CPU and its importance in modern computing. So, let’s dive in and discover the wonders of the CPU!
CPU stands for Central Processing Unit. It is the brain of a computer, responsible for executing instructions and performing calculations. It is made up of multiple components, including the arithmetic logic unit (ALU), control unit, and memory. The CPU is the primary component that performs the majority of the processing tasks in a computer, making it one of the most important components in a computer system.
What is a CPU?
A Brief History of CPU
The CPU, or Central Processing Unit, is the brain of a computer. It is responsible for executing instructions and performing calculations that make a computer work. The first CPUs were developed in the 1940s, and since then, they have undergone significant improvements in terms of speed, power efficiency, and complexity.
One of the earliest CPUs was the ENIAC, which was developed in the 1940s at the University of Pennsylvania. It was a large, heavy machine that used vacuum tubes to perform calculations. The ENIAC was the first computer to be able to perform mathematical calculations at a speed that was much faster than that of its predecessors.
In the 1950s, the development of the Transistor led to the creation of smaller and more efficient CPUs. The Transistor replaced the vacuum tubes used in the ENIAC and other early computers, and it allowed for the creation of smaller, more powerful computers.
The 1960s saw the development of the Integrated Circuit, which combined multiple transistors and other components onto a single chip of silicon. This allowed for the creation of even smaller and more powerful CPUs, and it led to the widespread use of personal computers in the following decades.
In the 1970s and 1980s, CPUs continued to improve in terms of speed and power efficiency. The introduction of the Microprocessor in the 1970s allowed for the creation of smaller, more powerful computers that could be used in a variety of applications.
Today, CPUs are an essential component of most electronic devices, from smartphones and laptops to servers and supercomputers. They are constantly evolving, with new models and designs being developed to meet the growing demands of modern technology.
The Functions of a CPU
A CPU, or Central Processing Unit, is the primary component of a computer that carries out the instructions of a program. It is often referred to as the “brain” of the computer. The CPU performs several functions that are critical to the operation of a computer. These functions include:
- Decoding and Executing Instructions: The CPU decodes and executes the instructions that are stored in the computer’s memory. This involves retrieving the instruction from memory, decoding it to determine what operation it specifies, and then performing the operation.
- Controlling the Flow of Data: The CPU controls the flow of data between the computer’s memory, input/output devices, and other components. It coordinates the transfer of data between these devices and ensures that the data is processed correctly.
- Managing Memory: The CPU manages the computer’s memory by allocating and deallocating memory as needed. It ensures that each program has access to the memory it needs and that the memory is used efficiently.
- Performing Mathematical Operations: The CPU performs mathematical operations, such as addition, subtraction, multiplication, and division, as part of its instruction set. These operations are essential for many types of computations, including scientific simulations, financial calculations, and image processing.
- Handling Input/Output Operations: The CPU manages the input/output operations of the computer, including reading data from input devices such as keyboards and mice, and writing data to output devices such as screens and printers.
Overall, the CPU is responsible for the overall coordination and management of the computer’s operations. It carries out the instructions of a program and manages the flow of data between the computer’s various components to ensure that the computer operates efficiently and effectively.
CPU Architecture
The central processing unit (CPU) is the brain of a computer. It performs calculations and processes instructions for the computer to function. The architecture of a CPU refers to the design and layout of its components. A CPU consists of two main parts: the control unit and the arithmetic logic unit (ALU).
The control unit manages the flow of data within the CPU and coordinates the actions of the ALU and other components. It fetches instructions from memory, decodes them, and executes them. The control unit also manages the input/output operations of the CPU.
The ALU performs arithmetic and logical operations on data. It adds, subtracts, multiplies, divides, and performs logical operations such as AND, OR, and NOT. The ALU uses binary arithmetic to perform these operations.
The CPU also contains registers, which are small amounts of memory that store data temporarily. There are several types of registers, including general-purpose registers, which can store any type of data, and special-purpose registers, which are used for specific tasks.
In addition to the control unit and ALU, the CPU contains other components such as a clock, which regulates the speed of the CPU, and a cache, which stores frequently used data to improve performance.
Overall, the architecture of a CPU is designed to efficiently execute instructions and perform calculations. It is a critical component of a computer’s hardware and plays a vital role in its performance.
What Does CPU Stand For?
The CPU, or Central Processing Unit, is the primary component of a computer that carries out the instructions of a program. It is responsible for executing instructions and performing calculations that make a computer work. CPUs have undergone significant improvements in terms of speed, power efficiency, and complexity since the development of the first CPUs in the 19940s. CPUs are an essential component of most electronic devices, from smartphones and laptops to servers and supercomputers.
The Meaning of CPU
A CPU, or Central Processing Unit, is the primary component of a computer that carries out instructions of a program. It is responsible for performing arithmetic, logical, input/output (I/O), and control operations specified by the instructions in the program.
The CPU is often referred to as the “brain” of the computer, as it executes the majority of the calculations and instructions required for the computer to function. It is composed of various components, including the control unit, arithmetic logic unit (ALU), registers, and buses, which work together to execute instructions and perform calculations.
The CPU is measured in terms of its clock speed, which is typically measured in GHz (gigahertz). The clock speed refers to the number of cycles per second that the CPU can perform, and a higher clock speed generally indicates a faster and more powerful CPU.
Overall, the CPU is a critical component of a computer, and its performance can greatly impact the overall functionality and speed of the system.
CPU vs. GPU: What’s the Difference?
When it comes to understanding the basics of CPU, it is important to differentiate between CPU and GPU. While both CPU and GPU are essential components of a computer, they serve different purposes.
CPU, or Central Processing Unit, is the brain of a computer. It is responsible for executing instructions and performing calculations. CPUs are designed to handle a wide range of tasks, from simple arithmetic to complex calculations. They are the primary component responsible for running software and applications on a computer.
On the other hand, GPU, or Graphics Processing Unit, is designed specifically for handling graphics and video processing. GPUs are optimized for tasks such as rendering images and videos, playing video games, and running software that requires intensive graphics processing.
One of the main differences between CPU and GPU is their architecture. CPUs are designed with a few powerful cores that can handle a wide range of tasks, while GPUs are designed with many smaller cores that are optimized for specific tasks. This allows GPUs to perform complex calculations much faster than CPUs, but at the expense of power efficiency.
Another key difference between CPU and GPU is their use of parallel processing. CPUs use parallel processing to perform multiple tasks simultaneously, while GPUs use parallel processing to perform a single task much faster than a CPU. This makes GPUs ideal for tasks such as video encoding, which can take hours on a CPU but can be completed in minutes on a powerful GPU.
Overall, while both CPU and GPU are essential components of a computer, they serve different purposes. CPUs are designed for general-purpose computing, while GPUs are optimized for specific tasks such as graphics and video processing. Understanding the differences between CPU and GPU can help you choose the right hardware for your specific needs.
CPU Types
Desktop CPUs
Desktop CPUs, also known as desktop central processing units, are processors designed for use in desktop computers. These CPUs are typically more powerful than laptop CPUs and are capable of handling demanding tasks such as gaming, video editing, and other high-performance applications.
There are several factors to consider when choosing a desktop CPU, including the number of cores, clock speed, and architecture.
Factors to Consider When Choosing a Desktop CPU
Number of Cores
The number of cores refers to the number of independent processing units within the CPU. The more cores a CPU has, the more tasks it can handle simultaneously. This can result in faster processing times and improved performance.
Clock Speed
Clock speed, also known as frequency or clock rate, refers to the speed at which the CPU can execute instructions. It is measured in GHz (gigahertz) and a higher clock speed means a faster CPU.
Architecture
CPU architecture refers to the design of the CPU and the way it processes information. Different architectures are better suited to different types of tasks, so it’s important to choose one that is compatible with your needs.
Overall, desktop CPUs are an essential component of any desktop computer and play a crucial role in determining its performance. By considering the factors listed above, you can choose a CPU that meets your needs and helps you get the most out of your desktop computer.
Laptop CPUs
Laptop CPUs, also known as mobile CPUs, are processors designed specifically for use in laptops and other portable devices. These CPUs are typically smaller and more power-efficient than their desktop counterparts, making them ideal for use in devices that require longer battery life and better portability.
One of the key differences between laptop CPUs and desktop CPUs is their TDP (Thermal Design Power), which is the maximum amount of heat that the CPU can dissipate without exceeding its specified temperature range. Laptop CPUs have a lower TDP than desktop CPUs, which allows them to run cooler and quieter, but may also limit their performance in more demanding tasks.
Another important factor to consider when it comes to laptop CPUs is their clock speed, which is measured in GHz (gigahertz). Laptop CPUs typically have a lower clock speed than desktop CPUs, which can impact their overall performance. However, many laptop CPUs also incorporate features such as Turbo Boost, which can temporarily increase their clock speed to provide a performance boost when needed.
In addition to these factors, laptop CPUs may also differ in terms of their number of cores and cache size. The number of cores can impact a laptop’s ability to perform multi-tasking and handle more complex tasks, while the cache size can affect its ability to quickly access frequently used data.
Overall, laptop CPUs are an essential component of any portable device, providing the processing power needed to run applications and perform tasks on the go. Understanding the basics of laptop CPUs can help you make informed decisions when choosing a laptop or other portable device, and can also help you troubleshoot any issues that may arise.
Mobile CPUs
Mobile CPUs, also known as mobile processors, are a type of central processing unit (CPU) designed specifically for use in portable devices such as smartphones, tablets, and laptops. These CPUs are typically smaller and more power-efficient than their desktop counterparts, which makes them ideal for use in devices that require long battery life and minimal heat output.
There are several key differences between mobile CPUs and desktop CPUs, including their architecture, performance, and power consumption. Mobile CPUs are designed to be more power-efficient, which means they use less power and generate less heat than desktop CPUs. This is achieved through a variety of techniques, such as reducing the number of transistors, optimizing the clock speed, and using low-power cores.
Another key difference between mobile CPUs and desktop CPUs is their architecture. Mobile CPUs are typically based on ARM architecture, which is designed to be more power-efficient and better suited to mobile devices. This architecture is different from the x86 architecture used in most desktop CPUs.
In terms of performance, mobile CPUs are generally not as powerful as desktop CPUs. However, they are capable of handling most tasks that are required for mobile devices, such as web browsing, email, and media playback. Some mobile CPUs are also designed to be more powerful than others, which allows them to handle more demanding tasks such as gaming and video editing.
Overall, mobile CPUs play a crucial role in the performance and functionality of portable devices. They are designed to be power-efficient, small, and lightweight, which makes them ideal for use in devices that require long battery life and minimal heat output.
CPU Cooling
Why CPU Cooling is Important
When it comes to understanding the basics of a CPU, it is important to consider the role that CPU cooling plays in keeping your computer running smoothly. The central processing unit, or CPU, is the brain of your computer, responsible for executing instructions and performing calculations. However, as the CPU works, it generates heat, which can cause the CPU to malfunction or even permanently damage it if not properly cooled.
That’s why CPU cooling is so important. It is designed to prevent the CPU from overheating, which can occur when the temperature of the CPU rises above a certain point. There are several different types of CPU cooling systems available, including air cooling and liquid cooling.
Air cooling involves using a heatsink and fan to dissipate the heat generated by the CPU. The heatsink is a metal plate that is in contact with the CPU, and the fan blows air over the heatsink to remove the heat. Air cooling is a reliable and cost-effective solution for CPU cooling, but it can be noisy and may not be suitable for use in smaller or quieter systems.
Liquid cooling, on the other hand, involves using a liquid coolant to absorb the heat generated by the CPU. The liquid coolant is pumped through a series of tubes and a radiator, which transfers the heat to the air, allowing it to dissipate. Liquid cooling is more effective than air cooling, as it can remove more heat from the CPU, but it is also more complex and expensive.
Regardless of the type of CPU cooling system used, it is important to ensure that the CPU is properly cooled to prevent damage and ensure optimal performance. Overheating can cause the CPU to slow down or even shut down completely, leading to system crashes and other issues. By investing in a good CPU cooling system, you can help prevent these problems and keep your computer running smoothly for years to come.
Types of CPU Coolers
When it comes to keeping your CPU cool, there are several types of coolers available on the market. Here are some of the most common types:
- Air Coolers
Air coolers are the most traditional type of CPU cooler. They consist of a heatsink and a fan that blows air over the heatsink to dissipate heat. Air coolers are relatively inexpensive and can be very effective if the heatsink is large enough and the fan is fast enough.
- Liquid Coolers
Liquid coolers use a liquid coolant to absorb heat from the CPU and transfer it to a radiator, where it is dissipated by a fan. Liquid coolers are generally more expensive than air coolers, but they can be more effective at cooling the CPU, especially if the radiator is large enough.
- All-in-One (AIO) Coolers
All-in-one coolers are a type of liquid cooler that come with a pre-filled liquid coolant and a radiator that is typically attached to the case. AIO coolers are easy to install and can be a good option for those who want a simple, all-in-one solution for cooling their CPU.
- Tower Coolers
Tower coolers are a type of air cooler that are taller and more massive than other air coolers. They typically have larger heatsinks and multiple fans, which can make them more effective at cooling the CPU. Tower coolers can be very quiet and can be a good option for those who want a high-performance air cooler.
- Thermal Paste
Thermal paste is a substance that is applied between the CPU and the heatsink to improve heat transfer. While thermal paste is not a type of CPU cooler in and of itself, it can be used in conjunction with any type of cooler to improve its performance.
Each type of CPU cooler has its own advantages and disadvantages, and the best type of cooler for your CPU will depend on your specific needs and budget. It’s important to choose a cooler that is compatible with your CPU and can handle the heat output of your specific processor.
How to Choose the Right CPU Cooler
Choosing the right CPU cooler is essential for maintaining the health and longevity of your computer’s central processing unit (CPU). Here are some factors to consider when selecting a CPU cooler:
1. Thermal Requirements
The first thing to consider is the thermal requirements of your CPU. Different CPUs have different thermal requirements, so it’s important to choose a CPU cooler that is capable of dissipating the heat generated by your CPU. Check the manufacturer’s specifications for your CPU to determine its thermal requirements.
2. Physical Compatibility
The second factor to consider is the physical compatibility of the CPU cooler with your computer’s case. CPU coolers come in different sizes and shapes, so it’s important to ensure that the cooler you choose will fit in your computer’s case without obstructing other components.
3. Noise Level
Another important factor to consider is the noise level of the CPU cooler. Some CPU coolers are designed to be quiet, while others can be quite loud. If you’re sensitive to noise, you may want to choose a cooler that operates at a lower decibel level.
4. Budget
Finally, your budget should also play a role in your decision. CPU coolers can range in price from $20 to $100 or more, depending on the brand, features, and quality. Set a budget and choose a cooler that fits within your budget while still meeting your other requirements.
By considering these factors, you can choose the right CPU cooler for your computer and ensure that your CPU runs smoothly and efficiently.
CPU Upgrades
How to Upgrade Your CPU
Upgrading your CPU can seem like a daunting task, but with the right tools and knowledge, it can be done with ease. Here are the steps to follow when upgrading your CPU:
- Shut down your computer and unplug it from the power source.
- Open the case of your computer and carefully remove the old CPU.
- Clean the old thermal paste off the CPU and apply new thermal paste.
- Place the new CPU into the socket and secure it in place.
- Close the case and plug the computer back in.
- Turn on the computer and test the new CPU.
It’s important to note that upgrading your CPU can be a delicate process, so it’s recommended to take your time and follow these steps carefully to avoid any damage to your computer. Additionally, it’s always a good idea to research the specific CPU you’re installing and ensure that it’s compatible with your motherboard and power supply.
How to Install a CPU
Installing a CPU is a complex process that requires technical expertise and specialized tools. Before attempting to install a CPU, it is important to ensure that the motherboard and other components are compatible with the new CPU. Here are the steps involved in installing a CPU:
- Power off the computer and unplug it from the power source.
- Open the case of the computer and remove the old CPU.
- Clean the CPU socket and the new CPU with a soft cloth to remove any dust or debris.
- Apply thermal paste to the CPU and place the new CPU into the socket.
- Align the CPU with the motherboard and tighten the CPU socket screws.
- Reconnect the power cable to the computer and turn it on.
- Test the computer to ensure that the new CPU is functioning properly.
It is important to note that the specific steps involved in installing a CPU may vary depending on the make and model of the computer. Additionally, it is recommended to consult the manufacturer’s instructions and seek professional assistance if necessary.
Benefits of Upgrading Your CPU
Upgrading your CPU can provide several benefits that can significantly improve your computer’s performance. Here are some of the most notable advantages of upgrading your CPU:
- Improved Performance: Upgrading your CPU can provide a significant boost in performance, especially when it comes to tasks that require a lot of processing power. This can include gaming, video editing, and other demanding applications.
- Increased Efficiency: A newer CPU can also make your computer more efficient, which can help reduce energy consumption and improve overall system stability.
- Enhanced Multitasking: Upgrading your CPU can also allow your computer to handle multiple tasks at once more effectively, making it easier to switch between applications and programs without experiencing lag or slowdowns.
- Future-Proofing: Finally, upgrading your CPU can help future-proof your computer, ensuring that it can continue to handle the demands of new software and applications as they are developed.
Overall, upgrading your CPU can provide a wide range of benefits that can significantly improve your computer’s performance and efficiency. Whether you’re a gamer, a content creator, or simply someone who relies on their computer for everyday tasks, upgrading your CPU can help ensure that your system is up to the task.
CPU FAQs
What is the difference between a 32-bit and 64-bit CPU?
A CPU (Central Processing Unit) is the brain of a computer, responsible for executing instructions and performing calculations. One of the key factors that determines the performance of a CPU is its bit-width, which refers to the number of bits it can process at a time. A 32-bit CPU can process 32 bits of information at a time, while a 64-bit CPU can process 64 bits of information at a time.
The difference between a 32-bit and 64-bit CPU is primarily related to the amount of memory they can address. A 32-bit CPU can address up to 4GB of memory, while a 64-bit CPU can address up to 128GB of memory. This means that a 64-bit CPU can handle more complex and larger programs than a 32-bit CPU.
In addition to the amount of memory that can be addressed, a 64-bit CPU also has the ability to perform more complex calculations due to the larger number of bits it can process at a time. This can result in faster processing times and improved performance for tasks that require a lot of computation, such as video editing or gaming.
Overall, the main difference between a 32-bit and 64-bit CPU is the amount of memory they can address and the complexity of the calculations they can perform. If you need a CPU for tasks that require a lot of memory or complex calculations, a 64-bit CPU may be a better choice.
How do I know if my CPU is compatible with my motherboard?
One of the most critical factors to consider when building a computer is ensuring that the CPU and motherboard are compatible. Here are some steps to help you determine if your CPU is compatible with your motherboard:
- Check the motherboard manual: The motherboard manual will list the compatible CPU sockets. Look for the CPU socket in the manual and compare it with the CPU socket on your CPU.
- Check the CPU manual: The CPU manual will list the compatible motherboard sockets. Look for the motherboard socket in the manual and compare it with the motherboard socket on your motherboard.
- Use CPU-Z: CPU-Z is a free software that provides detailed information about your CPU, including the socket type. Download and run CPU-Z, and check the CPU socket information.
- Use the motherboard BIOS: Restart your computer and enter the BIOS setup. Look for the CPU information in the BIOS and compare it with the CPU socket on your motherboard.
It is important to note that even if the CPU and motherboard have the same socket type, they may not be compatible if they are from different generations. Additionally, some CPUs may require a BIOS update to be compatible with a motherboard. Therefore, it is essential to do thorough research before purchasing a CPU and motherboard to ensure compatibility.
Can I upgrade my CPU without upgrading my motherboard?
One of the most common questions that arise when discussing CPU upgrades is whether it is possible to do so without also upgrading the motherboard. The answer to this question depends on several factors, including the type of CPU and motherboard you currently have, as well as the specific requirements of the CPU you wish to upgrade to.
In general, if you are looking to upgrade your CPU, it is likely that your motherboard will also need to be upgraded to accommodate the new CPU. This is because the motherboard is responsible for providing power and communication between the CPU and other components of the computer. If the new CPU requires more power or has different communication requirements than your current CPU, your motherboard may not be able to support it without an upgrade.
However, there are some cases where it may be possible to upgrade your CPU without upgrading your motherboard. For example, if you are simply looking to upgrade from a lower-end CPU to a higher-end CPU of the same socket type, it may be possible to do so without upgrading the motherboard. Additionally, some CPUs may have backwards compatibility with older motherboards, allowing for an upgrade without a motherboard swap.
It is important to note that attempting to upgrade your CPU without upgrading your motherboard can result in instability or even damage to your computer. Before attempting any CPU upgrade, it is important to do your research and ensure that all components are compatible with one another.
How long does a CPU last?
A CPU (Central Processing Unit) is a critical component of a computer system that determines its overall performance. It is responsible for executing instructions and managing data flow within the system. As such, the CPU is an essential component that requires regular maintenance and upgrades to ensure optimal performance.
The lifespan of a CPU depends on several factors, including usage, quality, and maintenance. Generally, a CPU can last for several years before it needs to be replaced. However, the actual lifespan of a CPU depends on the specific model and usage conditions.
CPUs that are subjected to heavy usage, such as those used in gaming or professional applications, may wear out faster than those used for basic computing tasks. Similarly, high-end CPUs with more advanced features and capabilities may have a shorter lifespan than entry-level CPUs.
To extend the lifespan of a CPU, it is essential to maintain it properly. This includes regular cleaning, ensuring adequate cooling, and avoiding overheating. Additionally, upgrading to the latest firmware and software updates can help improve the performance and stability of the CPU.
In summary, the lifespan of a CPU depends on several factors, including usage, quality, and maintenance. While a CPU can last for several years, proper care and maintenance are necessary to extend its lifespan and ensure optimal performance.
Can I use a CPU from an older computer in a newer computer?
One common question that many people have when it comes to CPUs is whether or not they can use a CPU from an older computer in a newer one. The answer to this question is not straightforward, as it depends on several factors.
Firstly, it’s important to note that CPUs are designed to work with specific types of motherboards and sockets. Therefore, if you want to use a CPU from an older computer in a newer one, you need to ensure that the CPU is compatible with the motherboard of the newer computer.
In addition to compatibility issues, there may also be performance differences between older and newer CPUs. Newer CPUs typically offer better performance and more advanced features than older ones, so using an older CPU in a newer computer may result in lower performance than expected.
Furthermore, using a CPU from an older computer may also impact the stability and reliability of the system. Older CPUs may not be able to handle the demands of newer software and operating systems, which could lead to system crashes or other issues.
Therefore, it’s generally not recommended to use a CPU from an older computer in a newer one. If you need to upgrade your CPU, it’s best to purchase a new one that is specifically designed to work with your motherboard and operating system. This will ensure maximum compatibility, performance, and stability.
FAQs
1. What is a CPU?
A CPU, or Central Processing Unit, is the primary component of a computer that carries out instructions of a program. It is the “brain” of the computer, performing tasks such as arithmetic, logical operations, and controlling the flow of data between different parts of the computer.
2. What does CPU stand for?
CPU stands for Central Processing Unit. It is the primary component of a computer that carries out instructions of a program. It is the “brain” of the computer, performing tasks such as arithmetic, logical operations, and controlling the flow of data between different parts of the computer.
3. What is the purpose of a CPU?
The purpose of a CPU is to execute instructions of a program. It is responsible for performing arithmetic, logical operations, and controlling the flow of data between different parts of the computer. It is the “brain” of the computer and is essential for the computer to function properly.
4. What are the different types of CPUs?
There are several types of CPUs, including desktop CPUs, laptop CPUs, mobile CPUs, and server CPUs. Desktop CPUs are designed for use in desktop computers, while laptop CPUs are designed for use in laptops. Mobile CPUs are designed for use in mobile devices such as smartphones and tablets, while server CPUs are designed for use in servers and data centers.
5. How does a CPU work?
A CPU works by using transistors to perform logical and arithmetic operations. It retrieves instructions from memory and executes them, using a control unit to coordinate the flow of data between different parts of the computer. The CPU is responsible for performing the majority of the calculations and operations that a computer requires.
6. How is a CPU different from a GPU?
A CPU and a GPU are both processors, but they are designed for different tasks. A CPU is designed for general-purpose computing, such as running applications and performing calculations. A GPU, on the other hand, is designed for performing complex mathematical calculations, such as those required for graphics rendering and scientific simulations.
7. Can I upgrade my CPU?
It depends on the specific CPU and motherboard you have in your computer. Some CPUs are designed to be easily upgraded, while others are not. Additionally, some motherboards may have limitations on the types of CPUs they can support. Before attempting to upgrade your CPU, it is important to research the compatibility of your current components and ensure that the new CPU will be compatible with your existing hardware.