Hardware
- Binary
- CPU
- RAM (Random Access Memory)
- Hard Drives
- Flash Memory
- Types of Memory and Funneling
- Display Connectors
- USB (Universal Serial Bus)
- Wireless
- Operating System (OS)
- Looking Underneath the Hood
Binary
- We use computers everyday
- Inside a computer are “0s and 1s”
- Computers use the binary number system to represent info
- How do computers represent info with just binary?
- Computers use the binary number system to represent info
- Consider the decimal number (what we human typically use) 123
- The rightmost column is the 1s column
- The middle, the 10s
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The leftmost, the 100s
100 10 1 1 2 3 - Thus we have 100 x 1 + 10 x 2 + 1 x 3 = 100 + 20 + 3 = 123
- Inside a computer, the binary 000 would represent 0, just like in our human world!
- However, in this case we are dealing with binary so:
- The right most column is the 1s place
- The middle, the 2s
- The leftmost, the 4s
4 2 1 0 0 0 - In the human world (decimal) we use powers of 10 for place values
- 100 = 1, 101 = 10, 102 = 100, 103 = 1000, etc.
- In the computer world (binary) we use powers of 2 for place values
- 20 = 1, 21 = 2, 22 = 4, 23 = 8, etc.
- The difference between decimal numbers and binary numbers is changing the base
- For the binary number 000, we have 4 x 0 + 2 x 0 + 1 x 0 = 0 + 0 + 0 = 0!
- However, in this case we are dealing with binary so:
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Consider the binary number 001:
4 2 1 0 0 0 - We have 4 x 0 + 2 x 0 + 1 x 1 = 0 + 0 + 1 = 1
- How do we represent the decimal number 2 in binary?
- We don’t need a 4, be we need a 2, and also no 1
4 2 1 0 1 0 - This gives us 4 x 0 + 2 x 1 + 1 x 0 = 0 + 2 + 0 = 2
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Likewise, the number 3 would be:
4 2 1 0 1 1 - As we need a 2 and a 1
- Thus, 4 x 0 + 2 x 1 + 1 x 1 = 0 + 2 + 1 = 3
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Similarly, 4 would be:
4 2 1 1 0 0 -
What about 7?
4 2 1 1 1 1 - Which yields 4 x 1 + 2 x 1 + 1 x 1 = 4 + 2 + 1 = 7
- What about 8?
- We can’t count to 8 without another bit (binary digit)
- We run into this in the real world too if we need a four-digit number vs a 3-digit number
- Start with the 1s, 10s, 100s place and add the 1000s
- Here we’ll add the next power of 2, 8
8 4 2 1 1 0 0 0 - 8 x 1 + 4 x 0 + 2 x 0 + 1 x 0 = 8
- We run into this in the real world too if we need a four-digit number vs a 3-digit number
- We can’t count to 8 without another bit (binary digit)
- Just like decimal numbers (base 10), numbers represent larger values on the left side and decrease as we move right.
- So if we wanted to compare the binary numbers 1001 and 1010 we could start on the far left side of the number and look for where the numbers differ. The one with a 1 will be larger than the one with a 0.
8 | 4 | 2 | 1 |
---|---|---|---|
1 | 0 | 0 | 1 |
1 | 0 | 1 | 0 |
- Even though computers only use binary, they can count as high as humans can!
- They do it with a smaller vocabulary, just 1 and 0.
- This is because it’s easier to represent two states in the physical world
- If you think of one of these bits as being a light bulb:
- 0 is off
- 1 is on
- Light bulbs just need electricity to turn on or off
- Electricity is sufficient to turn a switch on or off
- Inside a computer exists these switches called transistors
- Modern computers have billions!
- Turned off represents 0
- Turned on represents 1
- Inside a computer exists these switches called transistors
- If you think of one of these bits as being a light bulb:
- This is because it’s easier to represent two states in the physical world
- They do it with a smaller vocabulary, just 1 and 0.
- Using these transistors we can store values, store data, compute, and do everything we can with computers
- David demonstrates how transistors work using light bulbs
- So far all that we can represent is numbers
- A decision needs to be made on what pattern of 1s and 0s to represent letters, words, and paragraphs
- All computers can store is 0s and 1s
- To represent letters, we need a mapping of 0s and 1s to characters
- ASCII (American Standard Code for Information Interchange) does this
- 65 -> A, 66 -> B, 67 -> C, etc.
- 97 -> a, 98 -> b, 99 -> c, etc.
- ASCII also has mapping for punctuation symbols
- Programs like notepad, textedit, and Microsoft Word decide weather to display patterns of bits as letters or words
- Computers only store 0s and 1s, but the programs interpret those bits in a certain way
- For example, if Microsoft Word sees a pattern of buts representing the number 65, it will interpret that as “A”
- Computers only store 0s and 1s, but the programs interpret those bits in a certain way
- ASCII is limited
- Original ASCII is 7 bits, thus giving 128 characters
- Extended ASCII is 8 bits, yielding 256 characters
- Many symbols are not represented
- Original ASCII is 7 bits, thus giving 128 characters
- UNICODE is a bigger set of characters that includes written languages other than English and even emoji! 😲
- All are still represented by a pattern of bits
- Consider this pattern of bits: 01001000 01001001
- 16 bits or 2 bytes (1 byte = 8 bits)
128 64 32 16 8 4 2 1 128 64 32 16 8 4 2 1 0 1 0 0 1 0 0 0 0 1 0 0 1 0 0 1 1 x 64 + 1 x 8 1 x 64 + 1 x 8 + 1 x 1 72 73 H I - Using ASCII we get the word “HI”
CPU
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If you have heard that your computer has “Intel Inside,” it has an Intel processor in it
- The backside of the processor has pins that connect into the motherboard
- The motherboard is a circuit board made of silicon
- The CPU is the brain of the computer
- Does all the thinking
- Performs math in numbers fed to it
- Helps display numbers on a screen
- Adds or deletes numbers
- CPUs now can have multiple cores
- Cores are the devices inside the CPU that can preform mathematical operations, load info from memory, save info to memory, etc.
- The more cores, the more tasks a CPU can do at once
- CPUs now also support hyper-threading
- Where a single core will present itself as multiple cores to a computer’s operating system
- Systems on a Chip (SoaC) are when a CPU and more are all interconnected at once rather than attached to a motherboard
- Popular in phones, tables, and game consoles
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Raspberry Pi
RAM (Random Access Memory)
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Circuit board with chips that slides into a slot on the motherboard
- The chips store data
- Only stores data when the power is on
- Files and programs are loaded onto these chips when ran
- Fast memory
- The chips store data
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You can check your RAM and other specs:
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Windows Task Manager
- CPU chart shows when peak usage occurs
- GHz is the number of operations a CPU can perform per second (in billions)
- 1.94 GHz = 1.94 billion operations per second
- Logical processors in this case is 4, which means both cores support hyper-threading
- Each core will do two things at once as if 4 cores exist
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Mac System Profiler
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Hard Drives
- When you turn a computer off, you need a place to store data
-
A hard disk drive (HDD) stores this information
- RAM may store 1 GB, 2 GB, 4 GB, through 16 GB or so
- HDD stores 256 GB, 1024 GB (AKA terabyte or TB), 2 TB
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Inside a HDD, metal platters physically spin around
- Data is stored on these disks
- The reading heads move back and forth reading data from the device
- Uses tiny magnetic particles where north pole orientation represents 1 and south pole orientation represents 0
- Power is only needed to read or change the data
- Data is preserved when power is off
- Power is only needed to read or change the data
- David shows a video of a HDD running in slowmo
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- To store data in a hard drive, RAM sends data and instructions to the HDD
- The hard drive translates that data into voltage fluctuations
- Some signals spin the platters, others move the read/write heads
- Pulses sent to the read/write head turn on a magnet which creates a field that changes the polarity of a tiny portion of the metal platter’s surface
- Power is sent in different directions as to change polarity
- To read, the particles on the disk use their charge to move the read/write head.
- Pieces of a file can be spread out around the platters
- A special file keeps track of data’s location
- Anytime you have a physical device that moves over a period of time, things go wrong
- Dropping a HDD can corrupt files
- Platters spin slower than how fast electrons move
- The hard drive translates that data into voltage fluctuations
Flash Memory
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Solid state disk (SSD)
- Smaller (3.5 inch width for HDD vs 2.5 inch width for SSD)
- Still fits where old HDDs are
- No moving particles
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Inside, it looks a lot like RAM
- Much faster than HDD
- Programs/files load and save more quickly
- SSD theoretically don’t last as long as HDD
- Finite number of writes
- Smaller (3.5 inch width for HDD vs 2.5 inch width for SSD)
- Hybrid Drives
- Some GB of solid state memory and more GB or TB of HDD space
- Stores as much of frequently-needed data on the SSD
- Stores less frequently-needed data on HDD
- Flash memory also exists in the form of USB sticks
- Might store 1 GB, 16 GB, or more
- Portable
- External SSDs exist for more storage
- Might store 256 GB or more
- Can be used to share data with others without network usage
- Can also have external HDD
Types of Memory and Funneling
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There is a tradeoff between space, money, and speed of data transfer
- Data is pushed “down the funnel” to your CPU
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From the hard drive, data first goes to the RAM
- Theoretically, the CPU never has to wait for data to crunch
- There is a tiny amount of memory (bytes) called registers where numbers are stored for operations.
- Memory at the bottom is more expensive
- Disk is important for the long-term storage
- RAM is important as it stores programs you use simultaneously
- L3, L2, L1 cache are on the motherboard
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- Data is pushed “down the funnel” to your CPU
- As an analogy for memory, picture a candy store
- A customer approaches the counter and requests candy
- The shop owner then leaves the counter to grab the candy before returning moments later
- Not super efficient to walk all the way to the store room to grab candy
- Better to have a cache of memory
- Not super efficient to walk all the way to the store room to grab candy
- Instead, the shop owner leaves the counter to ready a cache of candy before the customers arrive
- When a customer comes, the candy can be distributed quickly
- Cache memory similarly helps the CPU in this manner
- We can see sizes of cache looking at computer specs like before
Display Connectors
- These sockets all connect to monitors or displays
- Mini DisplayPort are used form monitors
- HDMI is not only on laptops and computers but also TVs
- VGA is older, but still commonly uses on projectors
USB (Universal Serial Bus)
- Can plug in a whole range of peripheral devices including printers, keyboards, mice, scanners, etc.
- USB-A most common
- USB-B is often used for printers and scanners
- USB-C is newer and can be plugged in coming from different directions
- Other variants often exist for phones
- Older USB connections are slower when transferring data
- Hard drives can connect via USB
- Even if a hard drive is fast, if the USB is slow, the transfer of data will be slow
- Hard drives can connect via USB
Wireless
- Wifi is wireless internet
- Bluetooth allows devices such as wireless keyboards and headphones to connect to your computer
- Limited range
- This is ok as it is used for you to connect to your own device
- Limited range
Operating System (OS)
- Software that ensures all devices work and can intercommunicate
- MacOS and Windows are popular OS
- Can be installed by the user, but is typically done so by a manufacturer
- Installed on HDD or SDD so that it exists persistently without power
- When you hit power on your computer, the OS is loaded into RAM
- Gives you the graphical interface that you see
- Knows how to:
- Talk to your keyboard and mouse
- Display info on the screen
- Move things around in memory
- This is all thanks to device drivers installed with the OS
- Special software designed to talk to certain model of printer, camera, scanner, etc.
- When an OS doesn’t recognize a device, perhaps because it’s too new, you can download new device drives from the device manufacturer
- Teaches Window, MacOS, or Linux about that new hardware
- Future-proofing structure
- It’s this intersection of hardware and software that makes computers powerful!
Looking Underneath the Hood
- David and Colton Ogden look at the exterior of an old ThinkPad computer, examining ports
- Power bricks convert power from the wall into safe amounts for the computer
- David and Colton examine the inside of an old window desktop, highlighting the motherboard, heatsink, RAM, Hard Drive, etc.
- David and Colton then look inside a HDD
- Once exposed to air and dust, it’s no longer reliable enough to use
- David and Colton then look at a motherboard examining all the ports on it