On Common–Base Avalanche Instabilities in SiGe HBTs

“…However, experimental results for forced-I E operation do not show the existence of such a forbidden region. Instead, some discontinuities appear in the CB output characteristics [1][2][3][4]. To understand the experimental CB behavior we need to include high current effects in our analysis.…”

“…This, however, is not a trivial task due to the existence of several concurring (and interacting) mechanisms (impact ionization, self-heating, hot carrier degradation), and the fact that the SOA is also dependent on the driving conditions at the input port [1][2][3][4][5]. It is well known that the widely cited open-base breakdown voltage BV CEO , which limits the operation under forced-I B conditions, does not fully describe the operating limits in practical cases, since the base is not commonly driven by a large impedance [1,2].…”

“…However, the analysis of the operating limits under forced-V BE /I E conditions is made complex by the base current reversal which, combined to the ohmic drop across the base region, yields a current focusing in the center of the base [2]. This current crowding effect is thought to be responsible of anomalous current discontinuities observed in common base (CB) output characteristics [1][2][3][4].…”

Theoretical analysis and modeling of bipolar transistor operation under reversal base current conditions

“…However, experimental results for forced-I E operation do not show the existence of such a forbidden region. Instead, some discontinuities appear in the CB output characteristics [1][2][3][4]. To understand the experimental CB behavior we need to include high current effects in our analysis.…”

“…This, however, is not a trivial task due to the existence of several concurring (and interacting) mechanisms (impact ionization, self-heating, hot carrier degradation), and the fact that the SOA is also dependent on the driving conditions at the input port [1][2][3][4][5]. It is well known that the widely cited open-base breakdown voltage BV CEO , which limits the operation under forced-I B conditions, does not fully describe the operating limits in practical cases, since the base is not commonly driven by a large impedance [1,2].…”

“…However, the analysis of the operating limits under forced-V BE /I E conditions is made complex by the base current reversal which, combined to the ohmic drop across the base region, yields a current focusing in the center of the base [2]. This current crowding effect is thought to be responsible of anomalous current discontinuities observed in common base (CB) output characteristics [1][2][3][4].…”

Theoretical analysis and modeling of bipolar transistor operation under reversal base current conditions

“…A commonly quoted parameter used to define the operating limits of the bipolar transistor is the openbase breakdown voltage BV CEO . However, it has been noted that the maximum operating voltage in practical circuit configurations is actually larger than BV CEO [4]. In fact, common circuit configurations are not characterized by a large impedance on the base, so that SiGe HBTs can be safely biased above open-base breakdown voltage; practical circuit topologies using a common-base configuration include cascode stages, output buffers and differential pairs.…”

“…Unfortunately, when the device is biased above BV CEO the operation is more complex, since avalanche multiplication effects cause a base current reversal. This in turn results in a distributed ohmic drop across the base region yielding a current focusing in the centre of the base, known as the pinch-in effect [4][5][6]. Therefore, in order to predict the SOA boundaries encountered in realistic circuit applications, an accurate model for the pinch-in effect is required.…”

Avalanche multiplication and pinch-in models for simulating electrical instability effects in SiGe HBTs

Millimeter-Wave Switching Mode Power Amplifiers