SGI- rev. A UNIVERSAL SIGNAL INTERFACE UNIT This unit can recalibrate a speedometer signal or convert a speed signal from one type to another type. The different functions it can perform are as follows:. Recalibrate a high speed (4,000ppm 20,000ppm) signal for an OEM speedometer or engine/transmission computer. Do not use this unit to adjust a signal going to an antilock braking system. 2. Recalibrate a low speed (000ppm 4000ppm) signal for an OEM or aftermarket speedometer or fuel injection computer. 3. Convert a high-speed signal found on newer GM transmissions down to a low speed signal to run a speedometer, cruise control, or fuel injection computer. 4. Convert an 000ppm signal from an aftermarket signal generator to a 4000ppm or 2000ppm to run an OEM cruise control or fuel injection computer.. Convert a 000ppm signal from a VDO Hall Effect signal generator to an 000ppm, 4000ppm, or 2000ppm to run a cruise control or fuel injection computer.. Convert a 4000ppm signal from an OEM transmission speed sensor or ECM output to an 000ppm signal for an aftermarket speedometer.. Convert a signal from a flywheel gear-tooth sensor to an ignition tachometer signal (diesel tachometer application). Setup tips: If, without the interface, your speedometer reads much too fast, then you will most likely need to use application 3. If, without the interface, your speedometer reads about ½ what it should, then you will most likely need to use application. If your speedometer reads, but is just off, you will probably need application or 2. Each of the different applications will be described in detail in the following sections. Here is a general overview of the unit functions. The unit has 0 switches on it for setting the calibration and signal type. Switch OFF ON OUT3/4/ set for high speed in OUT3/4/ set for low speed in 2 Slower output Faster output 3-0 Calibration setting (see calibration table) The unit has different outputs for speed signals. Some of the outputs are AC (a voltage output that goes above and below ground) and some are open collector (a switch that closes to ground). The output functions are as follows: SW Sig In OUT OUT2 OUT3 OUT4 OUT OFF 4k-2k 2k AC 2k oc 000 AC 4000 oc 2000 oc ON 4k-k 000 AC 000 oc 4000 AC 4000 oc 2000 oc Connect the PWR terminal to 2V accessory, GND terminal to ground.
APPLICATION Recalibrate a high speed (4,000ppm 20,000ppm) signal for an OEM speedometer or engine/transmission computer. Do not use this unit to adjust a signal going to an antilock braking system. Anti-lock braking systems may not operate correctly or behave erratically due to the signal processing done to recalibrate the speed signal. These speed sensors have a two-pin connector that plugs into the transmission or transfer case. One of the wires will be a ground and the other will be the signal wire. The wires will usually go up under the dash and into the speedometer, vehicle speed buffer, or engine/transmission computer. The signal wire will need to be cut so the SGI- can recalibrate it. The sensor side of the wire will go to the SIG IN terminal. The speedometer or buffer side will go to the OUT terminal. If the speedometer does not operate correctly after installation of the SGI- you may need to switch to OUT2 instead of OUT. Connect the PWR terminal to a 2-volt accessory wire and connect the GND terminal to a good ground location. Begin with the switches as follows and then determine how far off the calibration is. OFF OFF ON ON ON ON ON ON ON ON You can determine how far the speedometer is off by having it checked with radar or following another vehicle going at a set speed. Once you know how far it is off at a certain speed, use the following equation and then look up the switch setting in the table. Actual speed ------------------------------- = Cal ratio speedometer reading Switches 2-0 set the calibration adjustment. As an example, if you are following a vehicle going at mph and your speedometer shows 0 mph, then: 2 3 4 9 0 ----- = 0.9 from the table: OFF-ON-ON-ON-ON-OFF-OFF-ON-ON 0 Dakota Digital SGI- A UNIVERSAL SIGNAL INTERFACE PWR GND Sig. In OUT OUT2 OUT3 OUT4 OUT Output Setup 2-0 CAL Select 2 volt accessory power GROUND Speed input signal 2000 ppm output 4000 ppm output 000 ppm output alternate calibrated output speed signal calibrated AC output signal 2
APPLICATION 2 Recalibrate a low speed (000ppm 4000ppm) signal for an OEM or aftermarket speedometer or fuel injection computer. Either two wire or three wire sensors can be recalibrated with this unit. Two wire sensors will typically have one wire as a ground and the other as the signal. Three wire sensors will have an additional power wire. You must first determine which wire is the signal. The signal wire will need to be cut so the SGI- can recalibrate it. The sensor side of the wire will go to the SIG IN terminal. The speedometer or computer side will go to the OUT terminal. If the speedometer does not operate correctly after installation of the SGI- you may need to switch to OUT2 instead of OUT. Connect the PWR terminal to a 2-volt accessory wire and connect the GND terminal to a good ground location. Begin with the switches as follows and then determine how far of the calibration is. ON OFF ON ON ON ON ON ON ON ON You can determine how far the speedometer is off by having it checked with radar or following another vehicle going at a set speed. Once you know how far it is off at a certain speed, use the following equation and then look up the switch setting in the table. Actual speed ------------------------------- = Cal ratio speedometer reading Switches 2-0 set the calibration adjustment. As an example, if you are following a vehicle going at mph and your speedometer shows 0 mph, then: 2 3 4 9 0 ----- = 0.9 from the table: OFF-ON-ON-ON-ON-OFF-OFF-ON-ON 0 Dakota Digital SGI- A UNIVERSAL SIGNAL INTERFACE PWR GND Sig. In OUT OUT2 OUT3 OUT4 OUT Output Setup 2-0 CAL Select 2 volt accessory power GROUND Speed input signal 2000 ppm output alternate 4000 ppm output 4000 ppm AC output alternate calibrated output speed signal calibrated AC output signal 3
APPLICATION 3 Convert a high-speed signal found on newer GM transmissions down to a low speed signal to run a speedometer, cruise control, or fuel injection computer. These speed sensors have a two-pin connector on the transmission or transfer case. One of the pins will be a ground and the other will be the signal. The ground pin will go to the GND terminal along with the ground wire. The signal pin will go to the SIG IN terminal. It is best to twist the signal and ground wires from the sensor around each other. This helps eliminate any electrical interference. If nothing else is connected to the speed sensor it does not matter which pin is used as the ground. Connect the PWR terminal to accessory power. The output connections will depend on your particular application. Here are some typical examples: OUT3, 000ppm AC: OUT4, 4000ppm oc: OUT, 2000ppm oc: most aftermarket speedometers and cruise controls most TPI computers and some OEM cruise controls most TBI computers and some OEM cruise controls Begin with the switches as follows and then determine how far off the calibration is. If you are using an adjustable speedometer, then you can skip the SGI- calibration and use the speedometer's calibration routine. OFF OFF ON ON ON ON ON ON ON ON You can determine how far the speedometer is off by having it checked with radar or following another vehicle going at a set speed. Once you know how far it is off at a certain speed, use the following equation and then look up the switch setting in the table. Actual speed ------------------------------- = Cal ratio speedometer reading Switches 2-0 set the calibration adjustment. As an example, if you are following a vehicle going at mph and your speedometer shows 0 mph, then: 2 3 4 9 0 ----- = 0.9 from the table: OFF-ON-ON-ON-ON-OFF-OFF-ON-ON 0 Dakota Digital SGI- A UNIVERSAL SIGNAL INTERFACE PWR GND Sig. In OUT OUT2 OUT3 OUT4 OUT Output Setup 2-0 CAL Select 2 volt accessory power GROUND 2000 ppm output signal 4000 ppm output signal 000 ppm output signal Speed input signal 4
APPLICATION 4 Convert an 000ppm signal from an aftermarket signal generator to a 4000ppm or 2000ppm to run an OEM cruise control or fuel injection computer. Either two wire or three wire sensors can be recalibrated with this unit. Two wire sensors will typically have one wire as a ground and the other as the signal. Three wire sensors will have an additional power wire. You must first determine which wire is the signal. The signal wire will be tapped into so the SGI- can read it. The sensor signal wire will go to the SIG IN terminal. Connect the PWR terminal to a 2-volt accessory wire and connect the GND terminal to a good ground location. If nothing else is connected to a two wire sensor, then connect one wire to the GND terminal also. The output connections will depend on your particular application. Here are some typical examples: OUT3, 4000ppm AC: OUT4, 4000ppm oc: OUT, 2000ppm oc: most TPI computers and some OEM cruise controls use this if OUT3 does not provide a good signal most TBI computers and some OEM cruise controls Begin with the switches as follows. You may not need to change the calibration from this initial setting. If you want to adjust the calibration ratio, see application 2. ON OFF ON ON ON ON ON ON ON ON APPLICATION Convert a 000ppm signal from a Hall Effect VDO signal generator to 000ppm, 4000ppm, or 2000ppm to run a cruise control or fuel injection computer. The Hall Effect sensor will have three wires. The white wire is the signal. The signal wire will be tapped into so the SGI- can read it. The sensor signal wire will go to the SIG IN terminal. Connect the PWR terminal to a 2-volt accessory wire and connect the GND terminal to a good ground location. The output connections will depend on your particular application. Here are some typical examples: OUT, 000ppm AC: OUT3, 4000ppm AC: OUT4, 4000ppm oc: OUT, 2000ppm oc: most aftermarket cruise controls most TPI computers and some OEM cruise controls use this if OUT3 does not provide a good signal most TBI computers and some OEM cruise controls Set the switches as follows. ON OFF OFF ON ON ON ON ON ON ON
APPLICATION Convert a 4000ppm signal from an OEM transmission speed sensor or ECM output to an 000ppm signal for an aftermarket speedometer. The speed sensors have a two-pin connector on the transmission or transfer case. One of the pins will be a ground and the other will be the signal. The ground pin will go the GND terminal along with the ground wire. The signal pin will go to the SIG IN terminal. It is best to twist the signal and ground wires from the sensor around each other. This helps eliminate any electrical interference. If nothing else is connected to the speed sensor it does not matter which pin is used as the ground. If you are picking up a signal coming out of the ECM there will be only one wire to the SIG IN. Connect the PWR terminal to accessory power and the GND terminal to ground. Connect OUT to your aftermarket electric speedometer. Set the switches as follows. Any calibration adjustment should be done at the speedometer. ON ON OFF ON ON ON ON ON ON ON APPLICATION Convert a signal from a flywheel gear-tooth sensor to an ignition tachometer signal (diesel tachometer application). For using a standard 4-- cylinder tachometer on a diesel engine, the SGI- can convert a flywheel sensor signal into an -cylinder gas ignition signal. Calibration is accomplished by counting the number of teeth on the flywheel or using another tachometer as a reference. The number of teeth are listed in the calibration table under the heading tach. When switch 2 is ON, the tooth count is divided by 4. This will cover from 32 to 2 teeth. An inductive, gear-tooth sensor such as VDO part 340 020 should be mounted so the teeth pass by the end of the sensor. The GND terminal on the SGI- should be connected to a good ground as well as to one of the terminals on the gear-tooth sensor. The SIG IN terminal will connect to the other terminal. Connect the PWR terminal to 2V accessory power. OUT4 will provide the signal to the tachometer. Set the programming switches as follows: OFF OFF See calibration table If your tachometer does not show any reading after installing the SGI-, use a voltmeter to check the voltage at OUT4 with it connected to the tachometer and the engine running. Once you have done this, contact a Dakota Digital technical service representative for assistance.
3 4 9 0 Cal Hi Cal Lo tach 3 An "N" switch value represents an ON position. A "F" switch value represents an OFF position. Cal Hi represents switch 2 ON. Cal Lo represents switch 2 OFF. Tach column is with switch 2 OFF. 4 9 0 Cal Hi Cal Lo tach 3 N N N N N N N N 4.000.000 2 N F N N N N N N 2. 0. 92 F N N N N N N N 2.000 0.00 2 F F N N N N N N.333 0.333 34 N N N N N N N F 3.99 0.992 29 N F N N N N N F 2.3 0.3 93 F N N N N N N F.94 0.49 2 F F N N N N N F.32 0.332 3 N N N N N N F N 3.93 0.9 30 N F N N N N F N 2.39 0.0 94 F N N N N N F N.99 0.492 20 F F N N N N F N.320 0.330 3 N N N N N N F F 3.90 0.9 3 N F N N N N F F 2.2 0. 9 F N N N N N F F.94 0.49 22 F F N N N N F F.33 0.32 390 N N N N N F N N 3.9 0.90 32 N F N N N F N N 2.2 0.3 9 F N N N N F N N.939 0.4 24 F F N N N F N N.30 0.32 392 N N N N N F N F 3.0 0.92 33 N F N N N F N F 2.99 0.0 9 F N N N N F N F.92 0.4 2 F F N N N F N F.299 0.32 394 N N N N N F F N 3.2 0.9 34 N F N N N F F N 2. 0.4 9 F N N N N F F N.90 0.4 2 F F N N N F F N.293 0.323 39 N N N N N F F F 3.93 0.94 3 N F N N N F F F 2.3 0.43 99 F N N N N F F F.9 0.44 20 F F N N N F F F.2 0.322 39 N N N N F N N N 3. 0.94 3 N F N N F N N N 2.0 0.40 200 F N N N F N N N.2 0.4 22 F F N N F N N N.20 0.320 400 N N N N F N N F 3.3 0.934 3 N F N N F N N F 2.4 0.3 20 F N N N F N N F.9 0.4 24 F F N N F N N F.24 0.3 402 N N N N F N F N 3.0 0.92 3 N F N N F N F N 2.3 0.34 202 F N N N F N F N. 0.44 2 F F N N F N F N.2 0.3 404 N N N N F N F F 3.3 0.92 39 N F N N F N F F 2.22 0.3 203 F N N N F N F F.42 0.40 2 F F N N F N F F.2 0.3 40 N N N N F F N N 3. 0.94 40 N F N N F F N N 2.0 0.2 204 F N N N F F N N.29 0.4 20 F F N N F F N N.2 0.34 40 N N N N F F N F 3.3 0.90 4 N F N N F F N F 2.49 0.24 20 F N N N F F N F. 0.44 22 F F N N F F N F.249 0.32 40 N N N N F F F N 3.0 0.90 42 N F N N F F F N 2.4 0.2 20 F N N N F F F N.03 0.4 24 F F N N F F F N.243 0.3 42 N N N N F F F F 3.0 0.9 43 N F N N F F F F 2.43 0. 20 F N N N F F F F.90 0.44 2 F F N N F F F F.23 0.309 44 N N N F N N N N 3. 0.9 44 N F N F N N N N 2.42 0. 20 F N N F N N N N. 0.444 2 F F N F N N N N.23 0.30 4 N N N F N N N F 3.3 0.3 4 N F N F N N N F 2.40 0.2 209 F N N F N N N F. 0.44 290 F F N F N N N F.22 0.30 4 N N N F N N F N 3.0 0. 4 N F N F N N F N 2.43 0.0 20 F N N F N N F N.3 0.43 292 F F N F N N F N.29 0.30 420 N N N F N N F F 3.43 0. 4 N F N F N N F F 2.42 0.0 2 F N N F N N F F.4 0.43 294 F F N F N N F F.23 0.303 422 N N N F N F N N 3.49 0. 4 N F N F N F N N 2.4 0.04 22 F N N F N F N N.30 0.432 29 F F N F N F N N.20 0.302 424 N N N F N F N F 3.43 0.9 49 N F N F N F N F 2.404 0.0 23 F N N F N F N F. 0.430 29 F F N F N F N F.202 0.300 42 N N N F N F F N 3.43 0.3 0 N F N F N F F N 2.393 0.9 24 F N N F N F F N.0 0.42 300 F F N F N F F N.9 0.299 42 N N N F N F F F 3.39 0.4 N F N F N F F F 2.3 0.9 2 F N N F N F F F.9 0.424 302 F F N F N F F F.9 0.29 430 N N N F F N N N 3.3 0.42 2 N F N F F N N N 2.30 0.93 2 F N N F F N N N.4 0.42 304 F F N F F N N N. 0.29 432 N N N F F N N F 3.34 0.3 3 N F N F F N N F 2.39 0.90 2 F N N F F N N F.3 0.4 30 F F N F F N N F.0 0.29 434 N N N F F N F N 3.32 0.3 4 N F N F F N F N 2.349 0. 2 F N N F F N F N.2 0.4 30 F F N F F N F N.4 0.294 43 N N N F F N F F 3.303 0.2 N F N F F N F F 2.33 0.4 29 F N N F F N F F.2 0.43 30 F F N F F N F F.9 0.292 43 N N N F F F N N 3.22 0.2 N F N F F F N N 2.32 0.2 220 F N N F F F N N.4 0.40 32 F F N F F F N N.4 0.29 440 N N N F F F N F 3.2 0. N F N F F F N F 2.3 0.9 22 F N N F F F N F.3 0.40 34 F F N F F F N F. 0.290 442 N N N F F F F N 3.24 0.0 N F N F F F F N 2.30 0. 222 F N N F F F F N.20 0.40 3 F F N F F F F N.3 0.2 444 N N N F F F F F 3.220 0.0 9 N F N F F F F F 2.29 0.4 223 F N N F F F F F.0 0.403 3 F F N F F F F F.4 0.2 44 N N F N N N N N 3.200 0.00 0 N F F N N N N N 2.2 0. 224 F N F N N N N N.00 0.400 320 F F F N N N N N.43 0.2 44 N N F N N N N F 3.0 0.9 N F F N N N N F 2.2 0.9 22 F N F N N N N F.90 0.39 322 F F F N N N N F.3 0.24 40 N N F N N N F N 3.0 0.90 2 N F F N N N F N 2.2 0. 22 F N F N N N F N.0 0.39 324 F F F N N N F N.33 0.23 42 N N F N N N F F 3.4 0. 3 N F F N N N F F 2.2 0.4 22 F N F N N N F F. 0.393 32 F F F N N N F F.2 0.22 44 N N F N N F N N 3.22 0.0 4 N F F N N F N N 2.24 0. 22 F N F N N F N N. 0.390 32 F F F N N F N N.23 0.2 4 N N F N N F N F 3.03 0. N F F N N F N F 2.23 0.9 229 F N F N N F N F.2 0.3 330 F F F N N F N F. 0.29 4 N N F N N F F N 3.04 0. N F F N N F F N 2.22 0. 230 F N F N N F F N.42 0.3 332 F F F N N F F N.3 0.2 40 N N F N N F F F 3.0 0. N F F N N F F F 2.2 0.4 23 F N F N N F F F.33 0.33 334 F F F N N F F F.0 0.2 42 N N F N F N N N 3.04 0.2 N F F N F N N N 2.20 0.2 232 F N F N F N N N.24 0.3 33 F F F N F N N N.03 0.2 44 N N F N F N N F 3.030 0. 9 N F F N F N N F 2.9 0.49 233 F N F N F N N F. 0.39 33 F F F N F N N F.099 0.2 4 N N F N F N F N 3.02 0.3 0 N F F N F N F N 2. 0.4 234 F N F N F N F N.0 0.3 340 F F F N F N F N.094 0.24 4 N N F N F N F F 2.994 0.49 N F F N F N F F 2.9 0.4 23 F N F N F N F F.49 0.34 342 F F F N F N F F.09 0.22 40 N N F N F F N N 2.9 0.44 2 N F F N F F N N 2.9 0.42 23 F N F N F F N N.4 0.32 344 F F F N F F N N.0 0.2 42 N N F N F F N F 2.90 0.40 3 N F F N F F N F 2.0 0.40 23 F N F N F F N F.40 0.30 34 F F F N F F N F.00 0.20 44 N N F N F F F N 2.943 0.3 4 N F F N F F F N 2. 0.3 23 F N F N F F F N.4 0.3 34 F F F N F F F N.0 0.29 4 N N F N F F F F 2.92 0.3 N F F N F F F F 2.42 0.3 239 F N F N F F F F.43 0.3 30 F F F N F F F F.0 0.2 4 N N F F N N N N 2.909 0.2 N F F F N N N N 2.33 0.33 240 F N F F N N N N.4 0.34 32 F F F F N N N N.0 0.2 40 N N F F N N N F 2.93 0.23 N F F F N N N F 2.24 0.3 24 F N F F N N N F.44 0.32 34 F F F F N N N F.02 0.2 42 N N F F N N F N 2. 0.9 N F F F N N F N 2. 0.29 242 F N F F N N F N.43 0.30 3 F F F F N N F N.0 0.24 44 N N F F N N F F 2.0 0. 9 N F F F N N F F 2.0 0.2 243 F N F F N N F F.430 0.3 3 F F F F N N F F.03 0.23 4 N N F F N F N N 2.44 0. 0 N F F F N F N N 2.09 0.2 244 F N F F N F N N.422 0.3 30 F F F F N F N N.049 0.22 4 N N F F N F N F 2.29 0.0 N F F F N F N F 2.090 0.22 24 F N F F N F N F.44 0.34 32 F F F F N F N F.04 0.2 490 N N F F N F F N 2.3 0.03 2 N F F F N F F N 2.0 0.20 24 F N F F N F F N.40 0.32 34 F F F F N F F N.04 0.20 492 N N F F N F F F 2.9 0.99 3 N F F F N F F F 2.03 0. 24 F N F F N F F F.399 0.30 3 F F F F N F F F.03 0.29 494 N N F F F N N N 2.3 0.9 4 N F F F F N N N 2.0 0. 24 F N F F F N N N.39 0.34 3 F F F F F N N N.032 0.2 49 N N F F F N N F 2. 0.92 N F F F F N N F 2.0 0.4 249 F N F F F N N F.34 0.34 30 F F F F F N N F.02 0.2 49 N N F F F N F N 2.3 0. N F F F F N F N 2.04 0.2 20 F N F F F N F N.3 0.344 32 F F F F F N F N.024 0.2 00 N N F F F N F F 2.3 0.4 N F F F F N F F 2.040 0.0 2 F N F F F N F F.39 0.342 34 F F F F F N F F.020 0.2 02 N N F F F F N N 2.23 0. N F F F F F N N 2.032 0.0 22 F N F F F F N N.32 0.340 3 F F F F F F N N.0 0.24 04 N N F F F F N F 2.09 0. 9 N F F F F F N F 2.024 0.0 23 F N F F F F N F.34 0.339 3 F F F F F F N F.02 0.23 0 N N F F F F F N 2.9 0.4 90 N F F F F F F N 2.0 0.04 24 F N F F F F F N.34 0.33 30 F F F F F F F N.00 0.22 0 N N F F F F F F 2. 0.0 9 N F F F F F F F 2.00 0.02 2 F N F F F F F F.340 0.33 32 F F F F F F F F.004 0.2 0 4 9 0 Cal Hi Cal Lo tach 3 4 9 0 Cal Hi Cal Lo tach
Setup tips: If, without the interface, your speedometer reads much too fast, then you will most likely need to use application 3. If, without the interface, your speedometer reads about ½ what it should, then you will most likely need to use application. If your speedometer reads, but is just off, you will probably need application or 2. Trouble shooting guide Problem Possible Cause Solution _ Speedometer will not Wrong output type. Try switching from an oc to AC output work at all. or from an AC to oc output. No input signal. Test for -20 volts AC at the signal in terminal with the wheels spinning. Grounding interference. Make sure both the speed sensor and SGI- are grounded at the same point. No power to SGI-. Check the power and ground terminals on the SGI-. Should be - V dc. Speedometer will not SGI- set for wrong input If switch is off, turn it on. read at low speeds type. Speed signal is too low. Check speed connections for ground problems or shorts. Test the ground connection between SGI- and sensor. Check for another device loading down the sensor. Speedometer will read Tach wire too close to Route the speed signal and tachometer when the vehicle is speed signal wire. wires away from each other to avoid sitting still. interference. Signal In and OUT wires Route the input and output wires away routed too close. from each other to avoid feedback. Ground interference. Make sure the speed sensor and SGI- are grounded together. Tech Support You can contact us with any questions you may have by phone, fax, or email. 40 W. ST St. N. Sioux Falls, SD 0 Phone: (0) 332-3 FAX: (0) 339-40 Email: dakotasupport@dakotadigital.com On line: www.dakotadigital.com