How to calculate number of bits in logical address and physical address when logical address space of 8 pages of 1024 word each, mapped to physical memory of 32 frames?

1How big is a word? How big is a frame? – Oliver Charlesworth Jun 24 '12 at 13:40

1i find this question on internet and those details are not consider in the question. – Thar1988 Jun 24 '12 at 13:48
15 is the correct answer
i think this is correct way size of logical address space is No. of pages * Page size = 8 * 1024 = 2^3 * 2 ^10 = 2^13 No. of bits for logical address is 13
Size of Physical address space is 2^5 * 2^10 = 2^15 No. of bits for physical address is 15
There are 8 pages in logical address space so, 2^3 = 8
then page size of 3bits
We have 1024 words(1 word = 2bytes) then, 1024 * 2 = 2048 bytes
which we can say that 2^11 = 2048
then so there are 11 + 3 = 14bits
are the total number of bits in a logical address.
Now coming towards the Physical address:
we have 32 frames so 2^5 = 32
we have 5bits for frame + 11 bits = 16bits
then we have 16bits for our physical address.
Offset for both pages and frames is the same to comply with design. In the problem, offset is 1024, so offset for page = offset for frame = 2^10.
Total bits needed to give logical address to each word of each page = 3+10.
Since there are 5 bits needed to uniquely define each frame,the Physical address will require 5+10 = 15 bits.
Consider the following room/floor analogy: Each floor in a hotel contains 10 rooms. The door in each room is labeled 01, 02, 03, ..., 10. Then you get off the elevator, there is a plaque with the floor number. There are 3 floors in this hotel: floors 1, 2, and 3. Therefore, you can say that, to eliminate the ambiguity in room numbers, you concatenate the floor number to the room in the following format: floor:room. So, 1:01 is different than 2:01, or 3:01.
Viewing this graphically:
1  01  02  03  04  05  06  07  08  09  10 
2  01  02  03  04  05  06  07  08  09  10 
3  01  02  03  04  05  06  07  08  09  10 
The floor number can be expressed with one digit. The room number can be expressed with two digits. To express the unique location of the room (floor:room concatenation), you need three digits. Replace floor with frame, and room with page.

1
After searching the internet, i could find the solution for the question.
Each page/frame holds 1K; we will need 10 bits to uniquely address each of those 1024 addresses. Physical memory has 32 frames and we need 32 (2^5) bits to address each frames, requiring in total 5+10=15 bits. A logical address space of 8 pages requires 3 bits to address each page uniquely, requiring 13 bits in total.
this tutorial will provide more details regarding this question
size of logical address space is No. of pages * Page size = 8 * 1024 = 2^3 * 2 ^10 = 2^13 No. of bits for logical address is 13
Size of Physical address space is 2^5 * 2^10 = 2^15 No. of bits for physical address is 15
here i think the main memory information is not needed at all.
Given Total no of pages = 8 and page offset is 1024.
we know that logical address spaces is = total no of bits required to represent total no of pages + bits required to map page offset
.
Hence total bits required = 3 (because total no of pages is 8 and to represent you need three bits) + 10 (page offset is 1024 so you need 10 bits) = 13 bits all total.
Thanks.