Let θ∈(1,2), and μθ be the Bernoulli convolution parametrized by θ, that is, the measure corresponding to the distribution of the random variable ∑n=1∞anθ−n, where the an are i.i.d. with probability of an=0 equal to 21. As is well known, μθ is either equivalent to the Lebesgue measure on supp(μθ), or singular. Recall that an algebraic integer >1 is called Pisot if all its other Galois conjugates are smaller than 1 in modulus. It is known that μθ is singular with dimμθ<1 if θ is Pisot. An algebraic integer θ greater than 1 is called a Salem number if all its other Galois conjugates are of modulus 1, except θ−1. I shall prove that (1) dimμθ=1 if θ is an algebraic non-Pisot number. (2) if θ is Salem, then μθ is equivalent to the Lebesgue measure on supp(μθ), with an unbounded density in Lp(supp(μθ)) for all p<∞. (3) Define βθ,x,n=#{a1…an:∃an+1…such that x=k=1∑∞anθ−k}. Then n→∞limnβθ,x,n=θdimμθ forμθ−a.e.x. (4) Put n=1⋃∞{k=1∑nakθk∣ak∈{−1,0,1}}={y0(θ)<y1(θ)<⋯}, and ℓ(θ)=n→∞liminf(yn+1(θ)−yn(θ)). I shall present a short proof of De-Jun Feng's famous theorem which states that ℓ(θ)=0 for all non-Pisot θ.