How do you implement a hardware random number generator in an HDL (verilog)?
What options need to be considered?
This question is following the selfanswer format. Addition answers and updates are encouraged.
How do you implement a hardware random number generator in an HDL (verilog)? What options need to be considered? This question is following the selfanswer format. Addition answers and updates are encouraged. 


As noted in Morgan's answer this will only produce a single random bit. The number of bits in the LFSR only set how many values you get before the sequence repeats. If you want an N bit random number you have to run the LFSR for N cycles. However, if you want a new number every clock cycle the other option is to unroll the loop and predict what the number will be in N cycles. Repeating Morgan's example below, but to get a 5 bit number each cycle:
Edit: Added a new version below which doesn't require you to do the math. Just put it in a loop and let the synthesis tool figure out the logic:
I would like to make the LFSR length parameterizable as well, but that is much more difficult since the feedback taps don't follow a simple pattern. 


This is a TRNG (True random number generator) that works on an FPGA. It is basically an LFSR type structure without the flip flops, so it is a combinatorial loop that runs continuously. The signal oscillates chaotically, when you combine several of these modules and XOR bits you get a truly random bit, since the jitter from each combines. The maximum clock rate you can run this at depends on your FPGA, you should test the randomness with a testing suite like diehard, dieharder, STS or TestU01. These are called Galois Ring Oscillators(GARO). There are other TRNGs which use less power and area, but they are tricker to operate and write, usually relying on tuning delays to make a flipflop go metastable.



An LFSR is often the first port of call. Implementation is relatively simple, a shift register with a number of terms XORd together to create the feedback term. When considering the implementation of the LFSR, the bit width of the random number and the repeatability of the number need to be considered. With N bits a Maximal LFSR will have An example 4 bit LFSR with taps a bit 0 and bit 4:
Choosing tap points and finding out the sequence length (number of numbers before it repeats) can be found from this table. For example a sequence of 17,820,000, 30 bits wide could use taps of :
The first would have a feedback term of:
If you are unsure of the order of the taps, remember that the MSB will always be a feedback point. The Last (tap) feedback point defines the effective length of the LFSR, after that it would just be a shift register and have no bearing on the feedback sequence. If you needed a sequence of 69,273,666 you would have to implement a 31 bit LFSR and choose 30 bits for your random number. LFSRs are a great way to create a 1bit random number stream but if you are taking multiple consecutive bits that there is a correlation between values, it is the same number shifted plus dither bit. If the number is being used as a dither stream you may want to introduce a mapping layer, for example swap every other bit. Alternatively use an LFSR of different length or tap points for each bit. Further ReadingLinear Feedback Shift Registers in Virtex Devices, 

