This paper is the first of two back-to-back articles describing the first high resolution study and analysis of the rovibrational structure of the (mainly) A-type ν₁ band, the (mainly) B-type ν₁+ν₇ band, and of the C-type ν₁-ν₉ and ν₁+ν₉ bands of nitric acid (H¹⁴N¹⁶O₃) centered at 3551.766 cm^-1, 4127.782 cm^-1, 3092.708 cm^-1, and 4006.974 cm^-1, respectively. For this, high resolution Fourier transform laboratory spectra in the 2.8 μm, 2.4 μm, 3.2 μm, and 2.5 μm spectral regions were recorded at the SOLEIL synchrotron. The ν₁ band is highly congested and perturbed and the identifications were often uncertain because of line overlap, due to the large value of the Doppler linewidths (∼0.003 cm^-1 HWHM at 296 K). However, combining the analysis of the ν₁ band with that of the ν₁-ν₉ difference band (centered at 3092.708 cm^-1) proved to be highly helpful. Surprisingly enough, it appeared that the 1¹ energy levels are affected by torsional splitting, probably due to anharmonic resonances coupling together the 1¹ levels with those of vibrational states involving high excitation in the ν₉ mode. Using an effective approach, we have generated a list of positions and intensities for the ν₁ band and for the ν₁+ν₉-ν₉ and ν₁+ν₇-ν₇ hot bands in the 2.8 μm region.