G4+ FURY ECU
A premium ECU with Onboard
The Fury has a similar spec level to the Xtreme but with
added Onboard Digital Wideband Lambda Control.
With 8 Peak and Hold injector drives and 6 ignition
drives the Fury can control up to 3 rotors or 6 cylinders with sequential
injection and direct spark, making it a great choice for professional
level motorsport or more demanding road car applications.
This ECU has the same features as the Xtreme but with the added benefit of Onboard Digital Wideband Lambda Controller, no separate box required. Higher accuracy, simple setup and long sensor life are some of the advantages compared to a separate analog input wideband device.
If it is sequential
injection and direct spark for 8 cylinders you are after, consider a Storm, Xtreme or Thunder.
Download the Fury Quickstart Guide
8/10* x Digital inputs
4 x Temperature inputs
9 x Analog inputs
2 x Trigger inputs
2 x Knock inputs
1 x LSU 4.9 Wideband lambda sensor input
*2 inputs required when using 2nd CAN Bus
8 x Peak and Hold injection drives
6 x Ignition drivers
10 x Auxiliary outputs^
+5V Sensor power supply
+8V Sensor power supply
^unused fuel and ignition drives can be used as
additional Aux outputs
2* x CAN bus
1x Serial (RS232) connection
1x USB tuning connection
Dimensions: 185mm(L) x 130mm(W) x 40mm(H) (without looms)
What's in the box?
Supplied with USB tuning cable and mounting bracket.
Requires “A” & “B” looms or “A” & “B” connector
kits (not supplied).
- Four stroke, two stroke, and rotary engines supported.
- Engines up to 12 cylinders supported (six cylinder sequential ignition).
- Rotary engines up to 3 rotors supported.
- Three fuel equation modes:
- Traditional mode for quicker and simpler tuning setup.
- Modelled mode, more complex, but delivers superior results.
- Modelled - Multi Fuel, similar to Modelled mode but provides accurate fueling regardless of fuel blend. Often used for system running petrol-ethanol.
- Support for group, sequential, group-staged, and sequential-staged injection configurations.
- Accurate modelling and adjustment of fueling based on:
- Intake manifold pressure
- Throttle position
- Engine size
- Fuel pressure
- Fuel temperature
- Fuel density
- Current blended fuel stoichiometric ratio
- Fuel charge cooling
- Engine coolant temperature
- Intake air temperature
- Charge temperature estimation
- Injector flow rate
- Support for high impedance (saturated) and low impedance (peak and hold) injectors. Configurable injector currents in peak and hold modes..
- 2D or 3D injector dead-time table with configurable axis.
- Injector short pulse width adder table for areas of non-linear injector flow.
- Advanced injector testing function that allows for control over total number of pulses, rate of pulses, and pulse length.
- Four cold start stages based on engine speed, fuel blend, and engine coolant temperature. Auto adjusts cold start settings based on current fuel blend.
- Optional 4D and 5D overlay tables with adjustable axis to allow more complex fueling arrangements to be setup.
- Switchable dual fuel tables to allow different fueling for different situations.
- Acceleration enrichment for when the engine is increasing in speed, with control based upon throttle position or intake manifold pressure.
- Configurable overrun fuel cut function for reducing emissions, improving fuel economy, and reducing chance of backfires.
- Close Loop Lambda compensation with lockouts for engine coolant temperature, throttle position, throttle position acceleration, start-up timer, and intake manifold pressure. Tuner is also able to configure the maximum trim the closed loop lambda is allowed to apply. Able to use two oxygen sensors to control closed loop lambda for banks on V and boxer engines. Capable of using narrow-band or wide-band oxygen sensors.
- Individual cylinder fuel trims are able to be applied to the engine, with the trim being a constant fixed value, or each cylinder able to have a 3D table with configurable axis from which the trim is selected.
- Set the injector timing anywhere within the engine cycle. Choose to use a single fixed value, or use a value selected from a 3D table with configurable axis. The injector timing can be configured to be the start, center, or end of the injection pulse.
- Staged injection which is fully configurable including minimum pulsewidth lockout and activation engine speed. Injector dead-time table and short pulse width adder table configurable for staged injectors.
- Auxiliary injection that can be used as a third stage of injection with each auxiliary injector able to have an individual 3D control table. Capable of being configured by duty cycle or millisecond units.
- Support for seven types of ignition system:
- Twin distributors
- Wasted spark
- Direct spark
- Rotary engine - leading wasted spark
- Rotary engine - leading direct spark
- Odd fire wasted spark
- Rising or falling spark edge.
- Millisecond and duty cycle ignition coil dwell modes. 2D or 3D dwell table with configurable axis.
- Adjustable ignition delay compensation
- Configurable spark duration
- Maximum ignition advance setting.
- Ignition test function that is capable of activating individual ignition coils for testing of wiring and ignition components.
- Idle ignition control based on RPM target error.
- Correction of ignition angle based upon engine coolant temperature or intake air temperature.
- Optional 4D and 5D overlay tables with adjustable axis.
- Switchable dual ignition tables to allow different ignition angles for different situations.
- Ignition angle blending between two tables.
- Fuel, Ignition and special Rotary limiting modes.
- Engine temperature dependent RPM limit.
- Dual engine temperature dependent map limits.
- Vehicle speed limit. Can be used for pit lane speed limiter.
- General purpose RPM limit 3D tables for user configurable limiting (eg low fuel or oil pressure limit).
- All limits have basic or advanced setup modes.
- Limits use a RPM and throttle position based control range to apply progressive fuel and/or ignition cut.
- Configurable ignition retard and fuel correction during limiting (not all limits).
- Special limiting modes for motorsport features such as anti lag, cyclic idle and launch control.
- Additional optional hard limit.
- Each limit mode also has the option of applying a hard limit in case the soft limit is not adequate.
- Startup lockout and activation delay on limiting (not all limits).
- System voltage limit.
- Three types of auxiliary output channel:
- On/OFF type outputs. Examples of use include relays, engines fans, and check engine lights.
- Frequency type outputs. Examples of use include idle speed control solenoids, variable valve timing solenoids, and shift lights.
- Electronic throttle outputs. Can be used for other functions if not using electronic throttle.
- Each auxiliary output can be used for a variety of different functions.
- Virtual auxiliary channels which can be used to consider up to three conditions and then switch to be active. The state of the virtual auxiliary channel can then be used to control outputs or other ECU functions.
- Timer functions which can be used to add a time condition to the control of an output or other ECU function.
- Unused auxiliary fuel and ignition channels can be used for the control of other ECU outputs.
- Auxiliary output channels are able to be set to a general purpose output function where up to three conditions can be used to control the output.
- Auxiliary output channels are able to be set to a general purpose pulse width modulated (PWM) function where the tuner can setup a 3D table with different duty cycles that are selected by the ECU based upon the current axis axis.
- Auxiliary output channels are able to be set to drive either low (ground) or high (+v).
- For receiving input signals which are either off or on.
- Two types of digital input channel:
- ON/OFF type signals that do not switch back and forth rapidly. Examples include a brake switch, an air conditioning request, and a transmission neutral/park switch.
- Frequency type signals, these are ON/OFF type signals that switch rapidly. Examples include wheel speed signals, variable valve timing cam position signals, and ethanol sensor signals. Frequency type digital input channels are also capable of receiving normal (slower) ON/OFF type signals.
- Each digital input channels has an optional pull-up resistor. This allows the digital channel to receive signals that switch to ground or to +v.
- For receiving input signals that vary in resistance or voltage.
- Analog temperature channels that are used for receiving a signal that varies in resistance with temperature. Examples include engine coolant temperature, intake air temperature, and fuel temperature signals. These channels have a selectable internal pull-up resistor that can be used for piggy-back type installations.
- Analog volt channels that are used for receiving a signal that varies in voltage from 0 to 5 volts. Examples include throttle position, manifold pressure, and oil pressure signals. These channels can also be used with temperature sensors but require an external pullup resistor to be installed.
- Calibration tables to support sensors for which a defined calibration does not already exist. This allows the tuner to enter data and get the sensor working quickly.
- Fault settings function that assists in identifying when a sensor or sensor wiring has an open circuit or short circuit occur. Each analog channel has its normal lower and upper voltage levels defined by the tuner, when the ECU measures a voltage outside this range it will use a substitute value entered by the tuner. This allows the engine to continue running until a repair can be done.
- For receiving information on engine position.
- Support for crankshaft and camshaft position sensors
- Optical, hall, or reluctor type position sensors are able to be used.
- Over 80 pre-defined trigger modes for many common engines from around the world.
- Three configurable trigger patterns that can be used for unsupported engine types.
- Four filter levels to remove interference and noise from the trigger signals.
- Trigger arming threshold table where the minimum signal voltage can be defined so that low voltage noise on the trigger signal will be ignored.
- Calibration function that assists the user to set the base timing of the engine.