The amount of virtual memory available is determined by the bitness of the operating system. For instance, in a 32-bit operating system, each process typically has access to a 4 GB virtual address space. This means that, theoretically, each process can address up to 4 GB of virtual memory.
However, the available physical RAM (installed memory) is a separate factor. In a 32-bit system, the total physical memory that can be addressed is limited to 4 GB as well. This includes both RAM and memory-mapped devices
So, even if you have, for example, 1 GB of physical RAM installed in a 32-bit operating system, each process can still theoretically address up to 4 GB of virtual memory. They only see the 4 virtual gigs that the OS is showing to them.
Now, you may be wondering, what if a process wants to access more physical addresses than the available ones that weren't occupied by other earlier active processes ?!
In that situation, the operating system can move
bytes of memory to secondary storage to make room in RAM for newly
requested memory, a process known as paging. Typically, the least used
memory gets paged first so that actively used memory can remain in RAM.
When the paged memory is needed, the OS must load it back into RAM.
Paging allows for greater virtual memory usage, at the cost of a performance hit incurred while bytes are moved to and from secondary storage.
Keep in mind that secondary storage is significantly slower than RAM.