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RAS - Row Address Strobe or Row Address Select.
CAS - Column Address Strobe or Column Address Select.
tRAS - Active to precharge delay. This is the delay between the precharge and activation of a row.
tRCD - RAS to CAS Delay. The time required between RAS and CAS access.
tCL - (or CL) CAS Latency.
tRP - RAS Precharge. The time required to switch from one row to the next row, i.e. switch internal memory banks.
tCLK - CLocK. The length of a clock cycle.
Command Rate - This is the delay between Chip Select (CS) or when a IC is selected and the time commands can be issued to the IC.
Latency - The time between when a request is made and the request is answered. I.E, if you are in a restaurant, the latency would be the time between when you ordered your meal to the time you received it. Therefore, in memory terms, it is the total time required before data can be written to or read from the memory.
Some of the above terms are more important to system stability and performance than are others. However, it is important to understand the role of each of these settings/signals in order to understand the whole. Therefore, the numbers 2-3-2-6-T1 refer to CL-tRCD-tRP-tRAS-Command Rate and are measured in clock cycles.
tRAS
Memory architecture is like a spreadsheet with row upon row and column upon column with each row being 1 bank. In order for the CPU to access memory, it must first determine which Row or Bank in the memory that is to be accessed and activate that row via the RAS signal. Once activated, the row can be accessed over and over until the data is exhausted. This is why tRAS has little effect on overall system performance but could impact system stability if set incorrectly.
tRCD
There is a delay from when a row is activated to when the cell (or column) is activated via the CAS signal and data can be written to or read from a memory cell. This delay is called tRCD. When memory is accessed sequentially, the row is already active and tRCD will not have much impact. However, if memory is not accessed in a linear fashion, the current active row must be deactivated and then a new row selected/activated. It is this example where low tRCD's can improve performance. However, like any other memory timing, putting this too low for the module can result in instability.
CAS Latency
Certainly, one of the most important timings is that of the CAS Latency and is also the one most people understand. Since data is often accessed sequentially (same row), the CPU only needs to select the next column in the row to get the next piece of data. In other words, CAS Latency is the delay between the CAS signal and the availability of valid data on the data pins (DQ). Therefore, the latency between column accesses (CAS), plays an important role in the perfomance of the memory. The lower the latency, the better the performance. However, the memory modules must be capable of supporting low latency settings.
tRP
tRP is the time required to terminate one one Row access and begin the next row access. Another way to look at this it that tRP is the delay required between deactivating the current row and selecting the next row. Therefore, in conjunction with tRCD, the time required (or clock cycles required) to switch banks (or rows) and select the next cell for either reading, writting or refreshing is a combination of tRP and tRCD.
tRAS
Next comes tRAS. This is the time required before (or delay needed) between the active and precharge commands. In other words, how long must the memory wait before the next before the next memory access can begin.
tCLK
This is simply the clock used for the memory. Note that Frequency is 1/t. Therfore, if memory was running at 100Mhz, the timing of the memory would be 1/100Mhz or 10nS.
Command Rate
The Command Rate is the time needed between the chip select signal and the when commands can be issued to the RAM module IC. Typically, these are either 1 clock or 2.