The generation frequency is ω ≈ k ω н in classical gyrotrons, where ω н = е B 0 / m is the electron cyclotron rotation frequency in a uniform longitudinal magnetic field with induction B 0 , e is the electron charge, m is the electron mass, k = 1, 2, 3… is the cyclotron frequency working harmonic number. Thus, the generation frequency ω being tuned is possible only by changing B 0 . This way is very inconvenient. It’s necessary a solenoid additional (control) winding. That difficulty can be eliminated in gyrotrons with crossed fields - electric 0 and magnetic 0 , here 0 ⊥ 0 . The frequency can be tuned by changing E 0 . This possibility can be realized at least two ways: a gyrotron based on a coaxial resonator with radial field E 0 ; a four-mirror gyrotron on traveling Т -waves with transverse in respect the traveling wave direction to uniform crossed fields – electric 0 and magnetic 0 . The single-screw electron flow has a rotation frequency , for the first gyrotron type, where , , Δ V is the potential difference between the inner (radius b 1 ) and outer (radius b 2 ) coaxial conductors, r 0 is the electron flow rotation radius. Thus, the generation frequency ω ≈ k ω н is determined by both B 0 and Δ V . Moreover, at Δ V = 0 the device becomes a classical high-orbit gyrotron, at B 0 = 0 a classical helitron. Therefore, at B 0 ≠ 0 and Δ V ≠ 0 it should be called a gyrohelitron, the generation frequency of which is tuned electrically - by changing Δ V . The article presents the design schemes of a gyrohelitron and a two-beam four-mirror gyrotron. In both cases, piezoelectric devices realize synchronous tuning of the frequency, just it allows the devices becoming fully electrically controllable. The following results were obtained for the gyrohelitron. Resonator field – H 211 , interaction on the second harmonic ω s ; a) narrow-band tuning 10 %: maximum efficiency – 55 %, minimum efficiency – 25 %; β 0 = v 0 / c = 0.27; q = v 0 ⊥ / v || = 2; b) broadband tuning 58 %: maximum efficiency – 18 %, minimum efficiency – 14 %; β 0 = v 0 / c = 0.2; q = v 0 ⊥ / v || = 2. The given results for the gyrohelitron indicate that it is promising to use electrical frequency tuning in a coaxial gyro-BWT and the amplification band in a gyro-TWT, since these devices do not require piezoelectric tuning of electrodynamic structures.