It is frowned upon to use links like that in your question. In this case the links provide adequate/good descriptions.
If you are studying the ARM processor (which is now plural) then you already understand processor registers. Another name for them is general purpose registers. They are at this high level of thinking very similar to variables in a program, they are right there in your function readily available to use. In ARM these would be r0,r1,r2,r3, etc.
The instruction register is more of a concept, there may have been a time and you could certainly design something this way, but now we have pipelines so there isnt just one place where an instruction lives. but barring that. How must a cpu work? It has to fetch an instruction from memory, flash or ram or lets leave it at those. Then the logic has to inspect those bits and determine what instruction it is, and then from there what to do with it.
I sure hope you are starting with the ARM Architectural Reference Manual for the ARMv5 or the oldest one you can find basically and then work forward from there. That old one is the better one for getting started and not overly complicated with all the protection and other features that come later it covers the nuts and bolts.
so lets take the thumb instruction add.
I assemble that and then disassemble I get
Disassembly of section .text: 00000000 <.text>: 0: 18d1 adds r1, r2, r3
And looking at the ARM ARM that is exactly what I expected the top 7 bits being 0b0001100 then three groups of three bits describing the three registers, two input operands one the destionation, not necessarily in that order.
So how could a processor do anything useful with this? First it has to get the instruction from memory so it does some kind of read (a fetch is just a read) from memory to get those bits 0x18D1. Then it needs to decode those bits. Well while it is decoding those bits it needs to store those bits for more than the duration of a clock cycle. That generally means it gets latched into a register. Well the general purpose registers are not where this goes, somewhere inside the processor we need to store this instruction. And if you want to call that an instruction register, so be it. While stored in the processor temporarily we can then decode those bits, some logic will recoginize the top 7 bits and say "hey everybody this is a three register add", and now the processor has to go to get those two input registers. General purpose or using your wikipedia terms, processor registers. Those might also get latched into other registers that feed the alu or feed an adder circuit or perhaps the addition happens without the need for that, depends on the design. The addition happens, and now the result needs to go to the destination register, another processor register. Along with the flags that go to yet another register, processor state register (generically) or PSR or in ARM terms CPSR.
Now with pipelines though it is more complicated, a pipeline is nothing more than an assembly line you have seen on documentaries, or perhaps have first hand knowledge. The pipeline is using your wikipedia page a line of instruction registers. or an array using programming terms. The instruction is fetched and hits the first stage in the pipe, and like an assembly line different tasks happen at each stage, at some point we decode the instruction, at some point the operands are requested and show up, at some point the addition happens, and the output has to go somewhere along with the flags. All the while as this addition moves through the pipe ideally right behind it is another addition. Just like a red car in the assembly line followed by a white and a green each hitting the same step in the process, put the wheels on put the doors on, etc.