Abstract: A radio frequency micro-electromechanical switch (RF MEMS switch) is described. Also described is a method of producing such an RF MEMS switch. The method can include depositing on a substrate a first sacrificial layer and producing a pattern. A first layer of metal is deposited on the first sacrificial layer and on the substrate. A pattern is produced to form a first RF line and a first MEMS membrane. A second sacrificial layer is deposited on the first RF line and a pattern is produced. A dielectric layer is deposited on the second sacrificial layer and then a pattern is produced to form a dome. The first and second sacrificial layers are removed through a dome opening. A second metal layer is deposited on the dome and on the substrate, and then a pattern is produced to plug the dome opening(s) and to form a second RF line.

Abstract: A power switch including input and output lines of characteristic impedance Z0, and a switching area connected serially between the input and output lines, the switching area being formed by N (integer?2) parallel conducting branches and i belonging to {1, . . . , N}, each conducting branch having, from input to output lines of the switch, an input line portion with characteristic impedance Zbei in series with a switching circuit in series with an output line portion with characteristic impedance Zbsi, the switching circuit configured, in a first state, to block passage of a signal between the input and output line portions of the conducting branch and, in a second state, to transmit a signal between the input line portion and the output line portion of the conducting branch with a maximum reflection coefficient of 0.316, each of the characteristic impedances Zbei and Zbsi ranging from 0.75*N*Z0 to 1.35*N*Z0.

Abstract: A radio frequency micro-electromechanical switch (generally referred to using the acronyms RF MEMS) is described. Also described is a method of producing such an RF MEMS switch.

Abstract: A radio frequency micro-electromechanical switch (generally referred to using the acronyms RF MEMS) is described. Also described is a method of producing such an RF MEMS switch.

Abstract: A micro-electromechanical-system (MEMS) switch (1) is formed in a substrate (2) and includes a first RF signal line (3) and a second RF signal line (4), a deformable membrane (5), an activator (7) configured to deform the membrane (5), a substrate track, and a membrane track. The RF signal lines (3, 4) are connected by one of the membrane track and the substrate track. A membrane RF ground (9, 10) is integrated into the membrane (5), and the membrane RF ground is electrically connected to a substrate RF ground (11, 12, 3, 14), the membrane RF ground framing and being formed parallel to at least one among the membrane track (8) and the substrate track, such that the RF ground (9, 10) closely follows the RF signal path, in order to guide the propagation of the RF signal of the first RF signal line (3) to the second RF signal line (4) when the switch is in the on state.

Abstract: A micro-electromechanical-system (MEMS) switch (1) is formed in a substrate (2) and includes a first RF signal line (3) and a second RF signal line (4), a deformable membrane (5), an activator (7) configured to deform the membrane (5), a substrate track, and a membrane track. The RF signal lines (3, 4) are connected by one of the membrane track and the substrate track. A membrane RF ground (9, 10) is integrated into the membrane (5), and the membrane RF ground is electrically connected to a substrate RF ground (11, 12, 3, 14), the membrane RF ground framing and being formed parallel to at least one among the membrane track (8) and the substrate track, such that the RF ground (9, 10) closely follows the RF signal path, in order to guide the propagation of the RF signal of the first RF signal line (3) to the second RF signal line (4) when the switch is in the on state.

Abstract: A microelectromechanical system switch includes a signal input line, a signal output line, a deformable conducting membrane electrically connected to the signal output line and including a contact dimple facing the signal input line, and an actuation electrode. The membrane has a planar round shape, with a radial opening in the direction of the signal input line, narrowing from the periphery towards the center of the membrane, the contact dimple being formed in the central region of the membrane, the actuation electrode has the same shape as the membrane, and the gap between the membrane, facing the actuation electrode, and the actuation electrode is an airgap only.

Abstract: A microelectromechanical system switch includes a signal input line, a signal output line, a deformable conducting membrane electrically connected to the signal output line and including a contact dimple facing the signal input line, and an actuation electrode. The membrane has a planar round shape, with a radial opening in the direction of the signal input line, narrowing from the periphery towards the center of the membrane, the contact dimple being formed in the central region of the membrane, the actuation electrode has the same shape as the membrane, and the gap between the membrane, facing the actuation electrode, and the actuation electrode is an airgap only.