A coupled resonator filter device is disclosed. The coupled resonator filter device includes a substrate with one or more acoustic reflector layers disposed over the substrate, a first lower electrode disposed over the one or more acoustic reflector layers, a first piezoelectric layer disposed over the first lower electrode, and a first upper electrode disposed over the first piezoelectric layer. The coupled resonator filter device further includes one or more acoustic coupling layers disposed over the first upper electrode, a second lower electrode disposed over the one or more acoustic coupling layers, a second piezoelectric layer disposed over the second lower electrode, a second upper electrode disposed over the second piezoelectric layer, and a first tuning capacitor having a first upper plate coupled to the first upper electrode and a first lower plate coupled to the first lower electrode.

A bulk acoustic resonator filter includes a plurality of bulk acoustic resonators connected between first and second radio frequency (RF) ports to form a frequency band, wherein each of the plurality of bulk acoustic resonators includes a first electrode, a second electrode, and a piezoelectric layer disposed between the first and second electrodes, the plurality of bulk acoustic resonators include first and second bulk acoustic resonators having different differences between a resonant frequency and an antiresonant frequency, and different ratios of a thickness of the piezoelectric layer to a total thickness of the first and second electrodes, and/or different thicknesses of the piezoelectric layer.

A resonator element for use in a filter is provided. The resonator element includes a first resonator acoustically coupled to a second resonator. The first resonator has terminals for incorporation in a filter structure. A tuning circuit is coupled to the second resonator to enable tuning of the resonator element.

In accordance with an embodiment, an RF system includes a transmit path having a first tunable transmit band stop filter, and a power amplifier coupled to an output of the first tunable transmit band stop filter, where the first tunable transmit band stop filter is configured reject a receive frequency and pass a transmit frequency; a receive path comprising an LNA; and a duplex filter having a transmit path port coupled to an output of the power amplifier, a receive path port coupled to an input of the LNA, and an antenna port, where the duplex filter is configured to pass the transmit frequency and reject the receive frequency between the antenna port and the transmit path port, pass the receive frequency and reject the transmit frequency between the antenna port and the receive path port.

A coupled resonator filter device is disclosed. The coupled resonator filter device includes a substrate with one or more acoustic reflector layers disposed over the substrate, a first lower electrode disposed over the one or more acoustic reflector layers, a first piezoelectric layer disposed over the first lower electrode, and a first upper electrode disposed over the first piezoelectric layer. The coupled resonator filter device further includes one or more acoustic coupling layers disposed over the first upper electrode, a second lower electrode disposed over the one or more acoustic coupling layers, a second piezoelectric layer disposed over the second lower electrode, a second upper electrode disposed over the second piezoelectric layer, and a first tuning capacitor having a first upper plate coupled to the first upper electrode and a first lower plate coupled to the first lower electrode.

Methods for manufacturing resonator structures and corresponding resonator structures are described. A first wafer including a first piezoelectric material is singulated and bonded to a second wafer.

An acoustic filter circuit for noise suppression outside resonance frequency is provided. The acoustic filter circuit includes a first filter branch and a second filter branch. The first filter branch and the second filter branch are both configured to resonate at a resonance frequency to pass a radio frequency (RF) signal, but in opposite phases. The acoustic filter circuit also includes a shunt circuit coupled between the first filter branch and the second filter branch. As discussed in various embodiments in the detailed description, the shunt circuit can be configured to protect the RF signal located inside the resonance frequency and suppress noises located outside the resonance frequency. As such, the acoustic filter circuit can provide improved noise rejection and reduce insertion loss.

Acoustic resonators, such as bulk acoustic wave (BAW) resonators, are disclosed that include phase shift structures. Acoustic resonators, including stacked crystal filters (SCFs) and coupled resonator filters (CRFs), may include inverted piezoelectric layers that are configured to provide built-in phase shift capabilities. Circuit topologies that include such SCFs may be provided with simplified structures and reduced loss. Circuit topologies with such CRFs may be provided with more symmetrical electrical connections and improved phase balance over operating frequencies. SCFs with phase shift structures may additionally include spurious mode suppression by modifying piezoelectric coupling profiles within one or more layers. Mode suppression configurations may include structures with one or more inverted polarity piezoelectric layers, one or more non-piezoelectric layers, one or more thicker electrodes of the SCF, and combinations thereof.

Acoustic resonators, such as bulk acoustic wave (BAW) resonators, are disclosed that include mode suppression structures. Acoustic resonators, including stacked crystal filters (SCFs), are disclosed that include spurious mode suppression by modifying a piezoelectric coupling profile within one or more layers of an SCF. Mode suppression configurations may include structures with one or more inverted polarity piezoelectric layers, one or more non-piezoelectric layers, one or more thicker electrodes of the SCF, and combinations thereof. Symmetric input and output electrical response for SCFs with mode suppression configurations may be exhibited by including piezoelectric materials with different electromechanical coupling values and/or by dividing stress profiles differently by configuring different thicknesses for input and output sides of SCFs.

Acoustic resonators, such as bulk acoustic wave (BAW) resonators and, in particular, acoustic resonators including stacked crystal filters (SCFs) are disclosed. SCF structures are disclosed with increased spurious free ranges by providing various arrangements of acoustically soft materials in one or more locations that correspond with high stress regions of one or more modes. For SCFs operating in first order modes, relative amounts of acoustically soft materials within shared electrodes may be increased. One or more additional layers of acoustically soft materials may also be added to SCF structures near shared electrodes. Accordingly, SCFs may be provided with increased frequency spreads between first order modes and second order modes.