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  • In our computers, the memory architecture inside of it is

  • so very important, because there's so much communication

  • that takes place between the CPU and the memory sticks

  • themselves.

  • Our memory is there, and it's usually managed by something

  • called the Northbridge You might also hear this referred

  • to as the Memory Controller Hub.

  • This Memory Controller Hub manages this communication

  • process between the CPU and the memory itself.

  • On our most modern CPU, we've even taken the Northbridge and

  • the memory controller aspects of that.

  • And we've integrated it directly into the CPU, so that

  • we can then go directly from the CPU to the memory itself,

  • thereby making that process even faster.

  • There's a lot of different kinds of memory that we might

  • use inside of our computer.

  • Some that is on the CPU itself, inside of that chip,

  • is used to store information.

  • Those are called registers inside of the CPU.

  • There's not a lot of information

  • set aside for registers.

  • There's just enough for that CPU to be able to operate.

  • And every CPU has a certain set of

  • registers that can be used.

  • Another type of memory that is often on the CPU itself,

  • sometimes it's just off the CPU, is a cache memory.

  • There is a level one, level two, a level three type cache

  • memory that you might find.

  • And this is generally created from static RAM.

  • This is very, very fast memory, because you have such

  • speed requirements between the CPU itself and the dynamic RAM

  • memory that's inside of our computers.

  • This dynamic RAM is where a lot of the information is

  • stored on our system.

  • Whenever we have 2 gig or 4 gig or 8 gigabytes of memory,

  • we're really referring to this dynamic memory that's inside

  • of our computer.

  • Sometimes we'll set aside some of the memory inside of our

  • computer to use for paging or to use for virtual memory.

  • So there's many places inside of our computer, either

  • directly on the CPU or on the motherboard itself, where

  • we're taking advantage of that memory.

  • Whenever we're transferring information in and out of

  • memory, we sometimes will refer to the bandwidth, or the

  • number of transactions that we can communicate in and out of

  • our memory systems.

  • This refers to the width of the memory bus.

  • Sometimes we're talking about the total number of bits and

  • bytes that we can transfer on a single clock

  • cycle of your computer.

  • If you ever look at the numbers in the specifications

  • for your computers, especially as it's related to the front

  • side bus-- or FSB--

  • that's generally referring to the total amount of

  • information that can be transferred during a normal

  • clock cycle.

  • And sometimes you'll hear that referred to as the bandwidth,

  • or the amount of information that could be transferred

  • during that time frame.

  • Sometimes we're referring to bandwidth as the total number

  • of bits that can be transferred back and forth

  • during a normal clock cycle.

  • Those total number of transfers are represented as

  • 8, 16, 32, or on the most modern memory, we're

  • transferring 64 bits at a time in and out of that memory

  • information.

  • If you ever look at the memory itself, there's a lot of

  • different chips that are on the memory modules.

  • The total number of chips is really irrelevant to how much

  • information is going to be transferred back and forth.

  • That specification is simply built into the architecture of

  • the memory modules and the motherboard this you

  • happen to be using.

  • If you're looking at the specifications of memory

  • that's on your motherboard, or maybe you need to upgrade the

  • memory that's inside of your system, one of the primary

  • specifications you'll find is the clock speed of the memory.

  • That's because with Synchronous Dynamic Random

  • Access Memory, the memory is synchronized to the clock rate

  • of the memory bus itself.

  • So you'll see a throughput number associated with that.

  • If we're talking about SDRAM, the number that's associated

  • with the memory, like PC 100, means that the memory clock

  • rate is 100 megahertz.

  • DDR memory, DDR2, and DDR3 memory does not use the memory

  • bus clock rate as the designation of the memory.

  • If you're talking about DDR memory, it will have a PC in

  • front of it.

  • For DDR2, its PC2.

  • And for DDR3, it's PC3.

  • And then the number that's immediately after that refers

  • to the throughput of that memory in a single clock

  • cycle, and it's measured in megabytes per second.

  • So PC-1600 means that this is DDR memory and it's rated at a

  • throughput of 1,600 megabytes per second.

  • If it's a PC3-6400, that's DDR3 memory, and it's rated

  • with a throughput of 6,400 megabytes per second.

  • When you're purchasing memory or upgrading the memory in a

  • computer, another thing you'll find is something called a

  • latency number.

  • And it's usually referred to as a CAS number, which stands

  • for Column Address Strobe.

  • Sometimes it stands for Column Address Select.

  • The specification usually is abbreviated with a CL.

  • That stands for the CAS latency.

  • And this is the number of clock cycles between a time

  • when a request is made to the memory to the time that you

  • start getting the data back from the memory bus.

  • So the lower the number, the less latency you're going to

  • have, and the faster that communication is going to be.

  • For example, if you had a DDR2 memory module it was rated at

  • a 667 megahertz speed with a CL 4, that is going to be

  • faster than the same speed memory with a CL 5.

  • The lower the latency, the faster the amount of data

  • transfered.

  • Another type of memory you'll run into, especially in really

  • important systems.

  • If you have a web server or a database server, you might use

  • this type of memory that's able to check itself.

  • One common type is one called parity memory.

  • That is memory that has an additional parity bit onto the

  • memory module itself.

  • And it's constantly checking the communication in and out

  • of that memory module.

  • If anything comes through and it does not match the parity,

  • then it's going to flag a message and stop communication

  • so that that particular error does not propagate itself to

  • the rest of the system.

  • It can't fix the problem, but it can stop the process and

  • give you an opportunity to restart things.

  • On very important servers, you have a different kind of

  • memory called Error Correcting Code memory.

  • And as the name implies, this is very similar to the parity

  • memory, but it can error correct itself.

  • Which means if it sees an error, it will correct that

  • error and still allow the process to continue.

  • And if you are running a database server or some other

  • type of machine that constantly needs to have all

  • of the uptime possible, we never need downtime for that

  • system, it's probably going to use something like Error

  • Correcting Code memory.

  • Some motherboards may be configured to use

  • multi-channel memory.

  • This is memory that has a maximum throughput if we're

  • filling up two or even three slots of memory on the

  • motherboard.

  • These are usually installed in pairs or trios, and the

  • motherboard itself will be colored so that we can see

  • exactly where we would put all three of them into our

  • motherboard.

  • So if we had three memory modules, we would try to find

  • three memory modules that were exactly the same, and we would

  • put them into the colored slots that matched.

  • We wouldn't put them into the top three.

  • We would try to put them in so that we can maximize the

  • memory bus on that computer.

  • We'll see these colors very often when we run into

  • multi-channel memory, and that should be your cue to make

  • sure that you install the memory in pairs or in trios,

  • depending on what that motherboard requires.

  • When you're looking at specifications of memory, you

  • may also see it referred to as single-sided memory and

  • double-sided memory.

  • This does not mean that the chips themselves are on one

  • side of the module or on both sides of the module.

  • That would be much too easy, of course.

  • This is really referring to how the memory is accessed.

  • It uses something called ranks of memory.

  • The memory modules--

  • the memory chips on the module itself--

  • are arranged into groups.

  • Sometimes there is a single rank that is accessed by the

  • memory controller.

  • Sometimes the memory controller can access multiple

  • ranks on a particular memory module.

  • And when there are two ranks on a memory module, is called

  • double-sided.

  • If there's only one rank of memory on a memory module, it

  • is a single-sided.

  • And if we look at some of the documentation that we'd find,

  • it may be called rows.

  • It may be called sides.

  • Or it may be called ranks.

  • But it's all referring to whether it is single-sided or

  • double-sided.

  • If you wanted to read up on where a good practical example

  • of this might be, you can go to Intel's website.

  • There is an 875P Chipset Memory

  • Configuration Guide there.

  • This is the very long URL associated with it.

  • But it's a PDF file that you can download that talks about

  • one rank being a single-sided DIMM, and two ranks being a

  • double-sided DIMM.

  • That's one good example of where you might find the

  • memory and the different ranks that would be used.

  • So check your motherboard documentation to see what type

  • of memory it's using, and then you can go back and look at

  • the memory configuration guide for your motherboard to

  • determine if it's single-sided memory or double-sided memory.

  • In your documentation, you may see something like this that

  • talks about the different speed of the memory.

  • This is DDR 266 or 333.

  • It talks about the total number of DIMMs that you would

  • put inside of your computer, and it talks about the number

  • of ranks per DIMM that can be accessed.

  • If there are two ranks, it is a double-sided DIMM.

  • If it is one rank, the documentation here clearly

  • states that it's a single-sided DIMM.

  • So don't be thrown by the term single-sided and double-sided

  • to refer to those physical single or

  • double sides of memory.

  • We're really talking about how the memory controller is

  • accessing different parts of that memory.

In our computers, the memory architecture inside of it is

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PCメモリを理解する - CompTIA A+ 220-801: 1.3 (Understanding PC Memory - CompTIA A+ 220-801: 1.3)

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    Hhart Budha に公開 2021 年 01 月 14 日
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