Automotive link uses single wire

In the automotive industry, in which the goal is to produce cars with simpler, lighter wiring looms, any interface that uses just one wire instead of two offers a distinct advantage. The circuit in Figure 1 implements a bidirectional link using a single wire, with the car's chassis or ground conductor providing a negative return path. The microcontroller communicates with the driver of the car by illuminating LED₁. The driver communicates by operating switch S₁. Detecting the switch closure requires no current sensing: The circuit simply exploits the fact that the forward voltage drop of a properly biased LED is usually two or three times the V_BE of a bipolar transistor. Q₁, LED₂, and Q₂ form a semiprecision current source. Q₃ in the receiver path detects the switch closure. When the microcontroller's TX pin goes high, Q₂ illuminates LED₂ and biases Q₁ on. Q₁ sources a constant current to LED₁ via R₂ and D₁.

Figure 1.	This circuit implements a bidirectional link using a single wire and a ground return.

LED₂ constitutes an inexpensive but effective voltage reference, which imposes a constant voltage across current-setting resistor R₁. Provided that you choose R₃’s value to suit Q₂’s base drive, you can set the current in LED₂ and the voltage across it to fairly precise and constant values. For example, with R₃ = 430 Ω, the current in LED₂ is approximately 10 mA with 5 V at Q₂’s base (TX high). If you use a device such as the HLMP-1000 for LED₂, its forward voltage remains constant at approximately 1.6 V, putting approximately 0.9 V across R₁. The resulting 20 mA or so flowing in Q₁ provides adequate brightness for LED₁ and remains acceptably constant with changes in V_B or temperature.

With S₁ open, R₆ biases Q₃ on, pulling the receiver pin, RX, low. RX remains low, regardless of whether LED₁ is on. When the switch closes, the values for R₄ and R₆ ensure that Q₃’s base pulls down to approximately 150 mV (with V_S = 5 V), thereby turning off Q₃ and allowing RX to go high. As long as the switch remains closed, RX stays high, whatever the state of the TX pin. Powering the current source directly from the car's battery voltage, V_B, rather than from the microcontroller's supply, not only relieves the burden on the low-voltage regulator, but also ensures that LED₁ receives proper bias, even with a very low value for V_S. Thus, provided that R₃, R₄, and R₆ have appropriate values, the circuit functions with V_S as low as 3 V or even lower. A further advantage is that you can replace LED₁ with several LEDs connected in series. With V_B = 12 V, the current source has adequate compliance to drive four or five LEDs.

R₂ is a nonessential component, but it reduces the power consumption in Q₁. D₁ provides positive overvoltage protection for the current source, and voltage-suppressor D₂ can protect against the harmful transients that systems often encounter in the harsh automotive environment. C₂ with R₄ provides a degree of noise filtering and has negligible effect on the switching of Q₃. You may need C₁ and R₅ to roll off Q₂’s frequency response to avoid the possibility of high-frequency oscillation. The transistor types are not critical; most devices with respectable current gain and adequate power rating are satisfactory. LED₂ provides a triple function. As well as acting as a voltage reference for the current source, it also provides local indication of the external LED status by illuminating in synchronism with LED₁. Additionally, it provides open-circuit (broken-wire) indication by turning off completely (even when TX is high) if the connection between D₁ and the external LED breaks – a feature that may be useful for troubleshooting purposes. In the event of a broken wire, little collector current flows in Q₁, and its base-emitter junction shunts LED₂; provided that R₁ is much smaller than R₃, the shunt steals LED₂’s bias current, thereby turning it off. Although the circuit was developed for an automotive product, you could easily adapt it for use in other applications in which a simple user interface must operate on a single line.