I know that we need to convert decimal, octal, and hexadecimal into binary, but I am confused about conversion of decimal to octal or octal to hexadecimal or decimal to hexadecimal. Why and where we need these types of conversion?

I'm there are occasional uses for this. One use case would be a little app that allows user who wants to convert decimal to octal ... like you can with lots of calculators. But I'm not sure I understand the point of the question. Standard libraries typically don't provide methods like 

Different bases are good for different purposes.
One sometimes will want to use numbers in one base for a purpose where another base is desired. Thus, the various conversion functions available. In truth, however, my experience is that in practice you almost never convert from one base to another much, except to convert numbers from some nonbinary base into binary (in the form of your language of choice's native integral type) and back out into whatever base you need to output. Most of the time one goes from one nonbinary base to another is when learning about bases and getting a feel for what numbers in different bases look like, or when debugging using hexadecimal output. Even then, if a computer does it the main method is to convert to binary and then back out, because current computers are just inherently good at dealing with base2 numbers and notsogood at anything else. One important place you see numbers actually stored and operated on in decimal is in some financial applications or others where it's important that "numberofdecimalplace" level precision be preserved. Sometimes fixedpoint arithmetic can work for currency, but not always, and if it doesn't using binaryfloatingpoint is a bad idea. Older systems actually had built in support for this in the form of binarycodeddecimal arithmetic. In BCD, each 4 bits acts as a decimal digit, so you give up a chunk of every 4 bits of storage in exchange for maintaining your level of precision in the baseofchoice of the noncomputing world. Oddly enough, there is one common use case for other bases that's a bit hidden. Modern languages with large number support (e.g. Python 2.x's 


If your workplace is stuck in IPv4 CIDR  you'll be doing quite a lot of bin > hex > decimal conversions managing most of the networking equipment until you get them memorized (or just use some random, simple tool). Even that usage is a bit fewandfarbetween  most businesses just adopt the lazy "/24 everything" approach. If you do a lot of graphics work  there's the chance you'll want to convert colors between systems and need to convert from hex > dec... most tools have this built in to the color picker, though. I suppose there's no practical reason to be able to do other than it's really simple and there's no point not learning how to do it. :) ... unless, for some reason, you're trying to do mantissa binary math in your head. 


All of these bases have their uses. Hexadecimal in particular is useful as a shorthand for binary. Every hexadecimal digit is equivalent to 4 bits, so you can write a full 32bit value as a string of 8 hex digits. Likewise, octal digits are equivalent to 3 bits, and are used frequently as a shorthand for things like Unix file permissions (777 = set read, write, execute bits for user/group/other). No one base is specialthey all have their (obscure) uses. Decimal is special to us because it reflects human experience (10 fingers) but that's really the only reason. 


MIME uses hexadecimal system for Quoted Printable encoding (e.g. mail subject in Unicode) abd 64based system for Base64 encoding. 


A real world use case: a program prints error code in decimal, to get info from a database or the internet you need the hexadecimal format, because the bits of the error 'number' convey extra info you need to look at it in binary. 

