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TLDR; The signal period is $24$ hours, eventhough you have your power spectrum indicating components with a smaller period. The components with period $6, 8, 12$ hrs also repeat themselves every $4 \times 6 = 24, 3 \times 8 =24, 2 \times 12 =24 $ hrs. So they all have, in a way, a common period of 24 hrs.

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> It gives me four seasonal patterns at periods of 24, 12, 08, and 06

This sounds like you get overtones. If your periodogram is a sort of Fourier spectrum, then this is not weird. It means that the daily pattern consists of more structure than just a single sine wave.

This doesn't mean that the period of the signal is smaller than 1 day. Below is an example signal constructed with several overtones (wave lengths smaller than 1 day), and you can see that the period of the signal is 1 day. The higher frequency signals influence the *shape* but not the period of the signal.

[![example of signal with period 1 day but many higher frequency components][1]][1]

The period of a function that is a sum of periodic functions is the [least common multiple](https://en.wikipedia.org/wiki/Least_common_multiple) of the periods of the functions in the sum.


    ### t is time for one week of data sampled every ten minutes
    t = seq(0,7*24*60,10)
    
    ### some example measurement of data that depends on sin waves with multiple sub-daily periods
    Td = (24*60)/(2*pi)  ### daily period
    y = 2 + sin((t+1000)/(Td)) + 0.4* sin((t+1200)/(Td/2)) + 0.1* sin((t+800)/(Td/3)) + 0.1* sin((t+1000)/(Td/4)) 
                      
    ### plot
    plot(t/24/60,y+rnorm(7*24*6,0,0.2),
         type = "l", xlab = "time in days", ylab = "signal",
         main = "example of signal with a daily period, but several overtones")


  [1]: https://i.sstatic.net/NPqI6.png