/** * @file trigger_gm.cpp * * @date Mar 28, 2014 * @author Andrey Belomutskiy, (c) 2012-2020 */ #include "pch.h" #include "trigger_gm.h" #define GM_60_W 6 static float addTooth(float offset, TriggerWaveform *s) { s->addToothRiseFall(offset + GM_60_W / 2, GM_60_W / 2, TriggerWheel::T_SECONDARY); return offset + GM_60_W; } /** * https://github.com/rusefi/rusefi/issues/2264 * GM/Daewoo Distributor on the F8CV */ void configureGm60_2_2_2(TriggerWaveform *s) { s->initialize(FOUR_STROKE_CAM_SENSOR, SyncEdge::RiseOnly); s->isSynchronizationNeeded = false; s->isSecondWheelCam = true; int offset = 1; for (int i=0;i<12;i++) { offset = addTooth(offset, s); } offset += 2 * GM_60_W; for (int i=0;i<18;i++) { offset = addTooth(offset, s); } offset += 2 * GM_60_W; for (int i=0;i<18;i++) { offset = addTooth(offset, s); } offset += 2 * GM_60_W; for (int i=0;i<5;i++) { offset = addTooth(offset, s); } s->addEvent360(360 - GM_60_W, TriggerValue::RISE); offset = addTooth(offset, s); s->addEvent360(360, TriggerValue::FALL); } void configureGmTriggerWaveform(TriggerWaveform *s) { s->initialize(FOUR_STROKE_CRANK_SENSOR, SyncEdge::RiseOnly); float w = 5; s->addToothRiseFall(60, w); s->addToothRiseFall(120, w); s->addToothRiseFall(180, w); s->addToothRiseFall(240, w); s->addToothRiseFall(300, w); s->addToothRiseFall(350, w); s->addToothRiseFall(360, w); s->setTriggerSynchronizationGap(6); } static int gm_tooth_pair(float startAngle, bool isShortLong, TriggerWaveform* s, float shortToothWidth) { int window = (isShortLong ? shortToothWidth : (15 - shortToothWidth)); int end = startAngle + 15; s->addEvent360(startAngle + window, TriggerValue::RISE); s->addEvent360(end, TriggerValue::FALL); return end; } /** * TT_GM_24x_5 and TT_GM_24x_3 * https://www.mediafire.com/?40mfgeoe4ctti * http://www.ls1gto.com/forums/archive/index.php/t-190549.htm * http://www.ls2.com/forums/showthread.php/834483-LS-Timing-Reluctor-Wheels-Explained * * * based on data in https://rusefi.com/forum/viewtopic.php?f=3&t=936&p=30303#p30285 */ static void initGmLS24(TriggerWaveform *s, float shortToothWidth) { s->initialize(FOUR_STROKE_CRANK_SENSOR, SyncEdge::Rise); /* * Okay, here's how this magic works: * The GM 24x crank wheel has 48 edges. There is * a falling edge every 15 degrees (1/24 revolution). * After every falling edge, a rising edge occurs either * 5 or 10 (= 15 - 5) degrees later. The code 0x0A33BE * encodes the pattern of which type of gap occurs in the * pattern. Starting from the LSB, each bit left is the * next gap in sequence as the crank turns. A 0 indicates * long-short (late rising edge), while a 1 indicates * short-long (early rising edge). * * The first few bits read are 0xE (LSB first!) = 0 - 1 - 1 - 1, so the pattern * looks like this: * ___ _ ___ ___ _ * |___| |_| |_| |___| |_ etc * * | 0 | 1 | 1 | 0 | * * ___ = 10 degrees, _ = 5 deg * * There is a falling edge at angle=0=720, and this is position * is #1 (and #6) TDC. If there's a falling edge on the cam * sensor, it's #1 end compression stroke (fire this plug!) * and #6 end exhaust stroke. If rising, it's exhaust #1, * compression #6. */ uint32_t code = 0x0A33BE; int angle = 0; for(int i = 0; i < 24; i++) { bool bit = code & 0x000001; code = code >> 1; angle = gm_tooth_pair(angle, bit, s, shortToothWidth); } } // TT_GM_24x_5 void initGmLS24_5deg(TriggerWaveform *s) { initGmLS24(s, 5); // This is tooth #20, at 310 degrees ATDC #1 s->setTriggerSynchronizationGap(2.0f); s->setSecondTriggerSynchronizationGap(0.5f); s->setThirdTriggerSynchronizationGap(2.0f); s->tdcPosition = 50; } // TT_GM_24x_3 void initGmLS24_3deg(TriggerWaveform *s) { initGmLS24(s, 3); // This is tooth #20, at 312 degrees ATDC #1 s->setTriggerSynchronizationGap(4.0f); s->setSecondTriggerSynchronizationGap(0.25f); s->setThirdTriggerSynchronizationGap(4.0f); s->tdcPosition = 48; }