Title :
Wafer-level selective transfer method for FBAR-LSI Integration
Author :
Hikichi, Kousuke ; Seiyama, Kazushi ; Ueda, Makoto ; Taniguchi, Shinji ; Hashimoto, Ken-ya ; Esashi, Masayoshi ; Tanaka, Shoji
Author_Institution :
Tohoku Univ., Sendai, Japan
Abstract :
This paper reports the wafer-bonding-based integration of heterogeneous devices with different die sizes by laser-assisted selective device transfer technique. 1 mm × 1 mm FBAR (film bulk acoustic resonator) dies supported with a glass wafer were selectively transferred to a wafer of 2 mm × 2 mm BiCMOS sustaining amplifiers by low temperature Au-Au bonding. The FBAR dies left on the support glass wafer were transferred to other BiCMOS wafers, and 4 times of integration were done in total using the same FBAR wafer. The integrated device worked as a chip-size-packaged 2 GHz timing oscillator, and a phase noise of -103 dBc/Hz at 10 kHz offset and -155 dBc/Hz at 1 MHz offset was confirmed.
Keywords :
BiCMOS integrated circuits; acoustic resonators; bulk acoustic wave devices; gold compounds; large scale integration; lasers; microassembling; microwave oscillators; wafer bonding; wafer level packaging; Au; BiCMOS sustaining amplifiers; BiCMOS wafers; FBAR wafer; FBAR-LSI integration; chip-size-packaged; die sizes; film bulk acoustic resonator dies; frequency 2 GHz; glass wafer; heterogeneous devices; large-scale integration circuit; laser-assisted selective device transfer technique; phase noise; timing oscillator; wafer-bonding-based integration; wafer-level selective transfer method; Bonding; Film bulk acoustic resonators; Glass; Gold; Large scale integration; Oscillators; Substrates; Au-Au bonding; FBAR oscillator; Integration; Selective transfer; Wafer-level packaging;
Conference_Titel :
Frequency Control Symposium (FCS), 2014 IEEE International
Conference_Location :
Taipei
DOI :
10.1109/FCS.2014.6859909
