A New Approach - The Symphony CHIP SET
The Significance of TransSiP PI in electronic systems
A REVOLUTIONARY APPROACH TO SUPPLY BIAS SIGNAL CONDITIONING
TransSiP's ground-breaking device level power integrity (PI) technology enables the use of digital power in low power and noise-sensitive applications, bringing advantages of stability, efficiency (i.e. longer battery life), and precision to wireless portable, wearable, remote, and IoT devices. Developed using a novel methodology employing cutting-edge real-time spectrum analysis techniques revealing signal details invisible to conventional spectrum and vector signal analyzers, TransSiP's innovative JC-PFM DC-DC conversion circuit topology is applicable to a broad range of noise-sensitive applications and compatible with system-in-package devices. This patents-pending design and methodology addresses the critical needs of noise-sensitive microsystems at the heart of portable, wearable, and IoT/M2M wireless communications and navigation for clean power and high conversion efficiencies in both full and standby power modes.
The insights provided by DPX® analysis and mathematical modelling led to the development of a new filtering concept for switched-mode PFM-type DC-DC converters. This new circuit topology can be implemented in the form of a discrete SiP component on the output of a PFM DC-DC converter, as a component set on a system motherboard, or as a complete DC-DC conversion solution: TransSiP's Symphony A2™ PI chipset.
Seeing is Believing...
The well-known components of PFM type switched mode DC-DC supply bias noise:
Output voltage ripple
Harmonics of switching frequency/frequencies
Ringing (due to parasitics)
Spurious or transient events
can be filtered and suppressed, although the variable frequency of PFM switched-mode converters can make this problematic. However, once ripple and noise on the supply bias is attenuated, TransSiP has found that noise amplitude is no longer the dominant factor.
Real-time spectrum analysis provided the answer: there are very short, varying interval transient and spurious events associated with a time domain component. This component, which TransSiP has termed “SNJ” (switching noise jitter) is what causes the chaotic noise signatures that compromise powered system performance.
Read Tektronix’ case study here.