Measurements of the characteristic length scale r_s of the baryon acoustic oscillations (BAO) provide a robust determination of the distance-redshift relation. Currently, the best (sub-per cent) estimate of r_s at the drag epoch is provided by Cosmic Microwave Background (CMB) observations assuming the validity of the standard Lambda CDM model at z sim 1000. Therefore, inferring r_s from low-z observations in a model-independent way and comparing its value with CMB estimates provides a consistency test of the standard cosmology and its assumptions at high-z. In this paper, we address this question and estimate the absolute BAO scale combining angular BAO measurements and type Ia Supernovae data. Our analysis uses two different methods to connect these data sets and finds a good agreement between the low-z estimates of r_{s} with the CMB sound horizon at drag epoch, regardless of the value of the Hubble constant H_0 considered. These results highlight the robustness of the standard cosmology at the same time that they also reinforce the need for more precise cosmological observations at low-z.