アプリケーションノート 3198

Modified LDO Sinks PECL-Termination Current


要約: By configuring a current-sinking negative LDO to operate as a positive-voltage sink, you can construct a low-voltage supply (1.3V) for terminating PECL-logic lines.

Also See: Modified LDO Regulator Sinks PECL-Termination Current

The positive emitter-coupled logic (PECL) used in high-speed telecommunications requires odd supply voltages: a positive VCC of +3.3V, and a termination voltage (VTT) equal to VCC -2V = +1.3V. The VTT supply is regulated with respect to VCC, and must be able to sink current.

Most positive low-dropout (LDO) regulators cannot sink current. Negative LDOs are designed for that purpose but normally deliver a negative voltage.

Figure 1 shows a current-sinking negative LDO modified for positive-voltage operation. The GND pin connects to VCC, and IN connects to ground. Those connections allow the negative LDO to operate as a positive-voltage sink in which the voltage at VSET equals VCC -1.25V:

Equation 1.

Figure 1.  The connections shown enable a negative-output LDO (with its inherent current-sinking ability) to generate a positive output voltage.
Figure 1. The connections shown enable a negative-output LDO (with its inherent current-sinking ability) to generate a positive output voltage.

The output voltage is regulated with respect to VCC. That feature is perfect for PECL-termination applications, because it requires the output voltage to track the VCC supply. Maximum output current is limited by the internal protection circuitry (to about 400mA) and by the package power-dissipation rating (about 550mW). For applications that require higher output voltage or higher current (or both), you can add series diodes to dissipate some of the power (Figure 2). You can add as many diodes as needed to dissipate power, but the voltage at OUT (Pin 5) must remain at least 300mV above ground (IN, pin 2).

Figure 2.  To operate the Figure 1 circuit at a voltage or current that would otherwise exceed IC1's internal or package power-dissipation ratings, add power-dissipating diodes as shown.
Figure 2. To operate the Figure 1 circuit at a voltage or current that would otherwise exceed IC1's internal or package power-dissipation ratings, add power-dissipating diodes as shown.