Datasheet
LM1949
SNLS349C –FEB 1995–REVISED MARCH 2013
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Typical Circuit Waveforms
Figure 18.
APPLICATION HINTS
The injector driver integrated circuits were designed to be used in conjunction with an external controller. The
LM1949 derives its input signal from either a control oriented processor (COPS™), microprocessor, or some
other system. This input signal, in the form of a square wave with a variable duty cycle and/or variable frequency,
is applied to Pin 1. In a typical system, input frequency is proportional to engine RPM. Duty cycle is proportional
to the engine load. The circuits discussed are suitable for use in either open or closed loop systems. In closed
loop systems, the engine exhaust is monitored and the air-to-fuel mixture is varied (via the duty cycle) to
maintain a perfect, or stochiometric, ratio.
INJECTORS
Injectors and solenoids are available in a vast array of sizes and characteristics. Therefore, it is necessary to be
able to design a drive system to suit each type of solenoid. The purpose of this section is to enable any system
designer to use and modify the LM1949 and associated circuitry to meet the system specifications.
Fuel injectors can usually be modeled by a simple RL circuit. Figure 19 shows such a model for a typical fuel
injector. In actual operation, the value of L
1
will depend upon the status of the solenoid. In other words, L
1
will
change depending upon whether the solenoid is open or closed. This effect, if pronounced enough, can be a
valuable aid in determining the current necessary to open a particular type of injector. The change in inductance
manifests itself as a breakpoint in the initial rise of solenoid current. The waveforms at the sense input show this
occurring at approximately 130 mV. Thus, the current necessary to overcome the constrictive forces of that
particular injector is 1.3 amperes.
Figure 19. Model of a Typical Fuel Injector
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