Title :
Distributed ESD protection for high-speed integrated circuits
Author :
Kleveland, Bendik ; Maloney, Timothy J. ; Morgan, Ian ; Madden, Liam ; Lee, Thomas H. ; Wong, S. Simon
Author_Institution :
Center for Integrated Syst., Stanford Univ., CA, USA
Abstract :
Conventional ESD guidelines dictate a large protection device close to the pad. The resulting capacitive load causes a severe impedance mismatch and bandwidth degradation. A distributed ESD protection scheme is proposed to enable a low-loss impedance-matched transition from the package to the chip. A simple resistive model adequately predicts the ESD behavior under stress according to the charged device and human body models. The large area of the distributed ESD scheme could limit its application to designs such as distributed amplifiers, rf transceivers, A/D converters, and serial links with only a few dedicated high-speed interfaces. The distributed ESD protection is compatible with high-speed layout guidelines, requiring only low-loss transmission lines in addition to a conventional ESD device.
Keywords :
analogue-digital conversion; circuit layout CAD; electrostatic discharge; high-speed integrated circuits; impedance matching; integrated circuit layout; integrated circuit modelling; transceivers; A/D converters; bandwidth degradation; capacitive load; charged device model; dedicated high-speed interfaces; distributed ESD protection; high-speed integrated circuits; high-speed layout guidelines; human body model; impedance mismatch; low-loss impedance-matched transition; low-loss transmission lines; resistive model; rf transceivers; serial links; Bandwidth; Biological system modeling; Degradation; Electrostatic discharge; Guidelines; High speed integrated circuits; Impedance; Integrated circuit packaging; Predictive models; Protection;
Journal_Title :
Electron Device Letters, IEEE
