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About Your New Sequential Gear System


Hopefully you have now purchased and received your new sequential gear system manufactured in house by Pfitzner Performance Gearbox. We would like to help you understand the various methods in which these systems can be used, installed and integrated into your car. We help explain some key information that will allow you to ask the correct questions and help you understand the best methods for installation into you're project. Lastly, we always say, if in doubt! Ask. We are a friendly team here at PPG and we are here to help.

What do I need to know?


Firstly you need to know what your new system is capable off! 99% of the time you will need the help of a expert in ECU calibration. You will also need to install the components into the gearbox case and for that you many need to seek one of our many experience installers.


Engineers, engine & gearbox mappers; calibrators vary in degrees of knowledge on the correct and best practice of programming sequential gear systems. We would like to provide a resource of information to enable a successful installation and calibration to give you years of good service and performance.

  • How are you going to operate? Lever shift or paddleshift?

  • What type of ECU do I have? 

  • Is my ECU mappable and able to provide any gear functions?

  • Do you have access to the ECU?

  • Do I have cable or drive by wire (DBW) throttle? 

  • Does my ECU have basic or advanced gear features?

  • Is my ECU OEM with aftermarket software available? 

  • Do I have access to a local calibrator for my ECU?


















Types of Installation

A awesome video from Motive DVD "What the Fast" they take a look at manual & sequential transmissions and explain the different parts of them. 





A helical and straight cut the same size, a helical is generally stronger due to the amount of teeth engaged at one time, it’s just that a straight cut can often be made to fit into a small space so in a small gearbox you can make a stronger gear than factory. It also has less axial load, so less stress on shafts and casing, so a small gearbox doesn't need as much strengthening with straight cut. Overall, there is no general rule to which is stronger, it comes down to application and design, obviously the team at PPG are biased :-) 

Gear Lever Operation


This is the standard option for sequential gearboxes and allows the driver to operate with a pull for upshift and push for downshift. The lever allows very good installation and very smooth gear changes can be calibrated. The normal operation of the system will be via a solid rod; linkage or Series 4 push pull cable. Each of these options comes with its benefits and enables the design to be optimised within the boundaries of the OEM installation.


The gear lever option has several variations available and calibrators decided based on the ECU systems ability as to what is best suited. As A company we always encourage end users to use a closed loop installation taking full advantage of any DBW (drive by wire) capability the ECU system may have.


Gear Lever – No ECU Control


This is the most basic installation and can yield great performance if the driver has the ability to modulate the throttle on up and down shifts simulating an engine cut. The method has its inherent risks and can allow power on shifts that can destroy the dog rings and put excessive strain on the drivetrain. Ideal for Hot Rod and historic carburetor type application where electronics are not wanted.


Gear Lever – Load Cell - Strain Gauge


In its very basic form the load cell method enables the calibrator visibility of when the driver is applying pressure or force to the gear lever. This information allows the calibrator to use this information to decide when and how long to cut the ignition or fuel in the ECU system to allow the torque on the transmission to reduce and allow the change to occur.


This system is widely used in lower tier racing as it offers a degree of simplicity but stops teams from automation of the gearshift phase. At PPG we don’t recommend this type of installation, basic cut time can cause power on engagement if the driver misses a shift which will result in damage very quickly.


However not all Load Cell based systems require an aftermarket ECU system to provide the cut phase. On many muscle cars in the USA we recommend to clients with OEM - factory ECU’s the “Lingenfelter cut box”.


This box will accept the load cell voltage and provide a cut based on force and time, therefore it is possible to determine the force at which to cut and the amount of time the cut should be maintained. We recommend customers cut based on barrel position and the initial movements they make to determine the cut start.


The system is very basic in its functionality but does provide some great installation and results with again the caveat of no protection should the driver miss shift during the shift phase.

Pseudo Closed Loop – Load Cell & Rotary Position S

This is a system that allows the usage of both the load cell and the rotary position to create a closed loop system using only basic ignition cut signals, such as with the common AEM ECU system. Currently they only support the most basic gear cut strategies and as above this can cause many problems should the driver have a failed shift using a time based cut strategy.


The EASY SHIFT from GEARTRONICS takes both input signals and uses the force to enable the cut and the rotary position voltage to signal the next gear state allowing the power to be handed back to the engine when the correct voltage is seen. They are a pretty smart box of electronics and for less than $600 you can have a system that offers a further degree of performance over basic timed cut; however they offer zero functionality to alter the 100% cut signal and zero ignition retard that a more advanced ECU can provide.



Gear Lever – Closed Loop Gearshift Operation with Integrated Rotary Position Sensor


This system is the optimal configuration for any sequential gearbox installed using lever operation. There are many variants, but to cover the main topic we will consider a gear lever with a load cell and sequential gearbox with a position sensor to read the rotary position of the sequential selector barrel.


Once you have a basic understanding of gear shift strategies you will understand why PPG’s exclusive technologies in the sequential gearbox market set them apart from any of their nearest competitor offerings.


The pioneering usage of the Gill Blade 360º sensor for rotary barrel position back in 2010 marked a turning point in data retrieval in transmission technology and turned a page to enable ECU calibrators to have previously undreamed of data acquisition. This system allows closed loop Motorsports ECU systems to see shift times down to as low as 38ms next gear stable. 

This beautiful JM-Imports R34 running a full closed loop system via a Syvecs ECU control system, calibrated by the formidable Romain Levesque of Uk based Race Cal Ltd. You can hear the throttle blips on the downshifts and the seamless upshifts, enabled via a DBW (Drive By Wire) throttle body. Also note how stable the car is during its shift phase. Key to a great package.

In-car in the R34 you can see the clutch is never operated during normal driving, even at low speeds! The car rev matches effortlessly on the downshifts. The lever has an in built motorsports load cell which works in closed loop with the Gill Blade 360º rotary sensor. You can see Romain never needs to use the clutch on either up or downshifts, regardless the road speed.



The below images are from the famous CALVO MOTORSPORTS Dodge Viper, calibrated by Collin Murphy - Ninjaeering. The data logs show a closed loop gearshift, the four images show the various states of a closed loop gear shift.  SHIFT - RECOVER - REARM - IDLE. From this information you can see the shift time and how fast the car recovers from each gear shift event. Just remember this car produces over 2000hp & 2000ftlb and still shifts with very small force. In fact the shift can be made with one finger even on full power. 






































































Paddle Shift – Air Shifted


We offer several options for paddle shift systems and installations. As a company we limit the amount of components we manufacture for paddle shift systems, instead working with Specialist companies whom offer complete systems. This allows us to focus on the design and installation of the pneumatic cylinder to the gearbox.


This option is in most cases a bolt on addition to the existing system and allows seamless integration to the OEM platform.


Our selected partner K-M-P based in The Netherlands has over 10 years experience in paddle shift engineering; designing and Manufacturing components to meet the exacting needs of the dynamic world of professional motorsport. All current paddle shift options come with a K-M-P pneumatic cylinder supplied and installed so customers can select any third party system they desire.  






























Gear Control Terminology


Closed Loop Gear Shift – Gear Lever


Closed Loop gearshift is the best and safest scenario for a sequential gear system. This state uses the key sensors we supply to enable as much visibility to the ECU as possible to avoid any power on shifting or forced downshifts. The load cell provides the ECU with the force input and the calibrator decides the point at which to start the cut phase, this is usually the point at which the barrel system starts to rotate. This requires some data logging to be reviewed so you can see the max force and force at which rotation starts.


Once the data is reviewed, the force of rotation; for example 14nm is reached the engine will enable the ignition cut to start and this will allow the gears to be disengaged and moved to the next gear position. Once the movement starts to happen on the selector barrel the rotary sensor takes over and sends a voltage output to the ECU. The calibrator in setup has already setup his system and logged the voltage in each gear to allow the ECU to know exactly what gear and state it is in. 


This great video shows Simon Richards beautiful R32 GT-R using a full closed loop gearshift strategy on the PPG R32 Sequential Gearbox. Using the KA Sensor Load Cell and Gill Blade 360º he has been able to create via a LINK ECU a closed loop gear change. Above all else listen to the audio to hear how seamless the car shifts. Great work Simon!

Flat Shift

Flat shift is a term used to describe a gear shift where the throttle remains at 100% and the gear change is completed. This is achieved using ECU calibration that allows very accurate ignition and fuel cuts to allow the gearbox to reduce the torque and load on the gearbox. Once the ignition cuts take effect the gear can be moved into the next higher gear. Flat shift can be very complex in modern ECU systems with lots of data and sensors contributing to this import phase of a sequential gearbox. Correct flat shift calibration can make sure the chassis stays balanced and seamless and in return provide the driver with a very neutral and balanced chassis during the gear change phase. 

Next Gear Stable 

Next gear stable can be defined by dog ring position being in such position of engagement the gearbox can accept torque back and the gear shift will be completed. Typically next gear stable can be set with per gear offsets to allow the gearbox to return torque once, for example 80% engagement. This can allow gear changes to be completed and returned to full power sooner; which we all know results in faster lap times.


Throttle Blip Downshift  

Throttle blips on downshift allow gear speeds to be equalized which allow accurate and fast downshift changes under deceleration. Failure to have correct matching gear speeds lead to wheel lock up and chassis instability. Correctly calibrated throttle blips decrease lap times.

Glossary – Gear System Components


Rotary Position Sensor


A sensor that allows a rotary movement to be converted to a voltage or PWM (Digital). All rotary sensors however were not created equal. At Pfitzner Performance Gearboxes we have pioneered the usage of contactless rotary sensors in sequential gear systems, this allows the sensor to avoid reading any vibrations and the sensor itself has the ability to be configured and calibrated for any rotation cycle. The sensors high resolution enables the barrel and dog ring position to be monitored which in turn allows the ECU to characterise the positions in which to return power. If you know the position you can decide the best point to remove and return power to the transmission.

The 5-wire sensor is 10-bit resolution and allows data capture at high frequencies, which yields real time benefits for ECU calibration and has full health check and configurable software. The sensors are hermetically sealed and are long term temperature and oil stable in operation allowing the sensors to be installed internally in our systems as they require zero service during their operational life.


PPG use exclusively; Gill Blade 360 º Sensors – 10bit resolution contactless rotary position sensors.






Load Cells – Strain Gauge


A load cell is a sensor that converts force (nm) into a voltage (volts). This allows the load cell to be optimised and calibrated for force input and voltage output. PPG supply load cells configured to operate for up shift and downshift operation, this means that the 0-5vdc output is split into half and the load cell is at its neutral/rest position at 2.5vdc allowing the ECU system to determine what is a pull (up) or push (down) on the gear lever. Sensors can be supplied for 0-12vdc operations and various force ranges. The Load cell we supply is optimised for a centered voltage at 2.5vdc and the force range is selected based on real time tests for the system purchased, so you can be assured the components will work exactly as advised in the field.


PPG use exclusively KA Sensors for all load cell applications, custom calibrated and designed for each application in the PPG sequential gearbox range.











Gear Lever


The sequential gear levers we supply are billet Aluminium construction with over sized pivot bearings which allow precision low friction bearings to be incorporated in the design. We offer two versions of lever, actuation above and below the pivot. This gives the option to pull or push for up and downshifts, all dependent on the individual application and requirements. Reverse is catered for with a small ergonomic mountain bike derived lever system that allow adjustment for each application.















Flappy Paddles - Paddle Shift

Used and seen a lot in modern DCT cars today. The paddles in motorsport applications are used to shift or actuate the next gear,either up shift or downshift. This function is via a small switch mounted into the paddle assembly. When a signal is sent, the ECU reacts to its input and signals the gearbox to change gear. This function works to actuate the gear shift pneumatic cylinder mounted on the gearbox. 










Pneumatic Gear Shift Cylinder 


Air actuators are compact and low weight. Air actuators produce very high force output from a very small physical size & weight. Actuators produce approximately 75Kg (750N) force when operated at 8.0bar (120psi). Pneumatic cylinders do not suffer reductions in force output when the temperature increases and require little additional thermal management considerations. Pneumatic systems only place small requirements of kinetic energy from the vehicle's electrical system during the shift phase.


The air compressor requires minimal electrical power and current long term and consume lest than 1amp per shift. 










Dog Rings 

You hear everyone talk about dog rings and wonder what exactly are they? Well in very simple terms they are the parts that move when you change gear between the two gears. They are the front line in making sure you get the next gear or not! So they are pretty important for the operation of a gearbox, they determine how a gearbox gets a gear and also releases a gear. PPG have some very unique features that other unscrupulous companies have tried to copy to their failure..... The way we design and heat treat our dog rings and dog gears sets us apart in so much; its not uncommon to hear of PPG gear systems having covered several years racing without any significant wear being visible. We design our systems to last and this is one of the many reasons they do so in so many high power, drift, race and rally applications.



Synchro, or Synchromesh as its widely known. The dictionary definition is a device in a transmission system that automatically brings the gears being meshed to about the same speed of rotation before a shift occurs. Basically it stops the gearbox from crashing or smashing gears!

Our dog rings in our dog boxes replace the synchro systems in order to be stronger, with quicker engagement when shifted fast. Did you know it is the synchro hub that move when you change gear and not the gears themselves!  


















Sequential Barrel

The “Barrel” as it is referred to in the motorsport’s world, is the item that holds the gear selectors in place and transfers motion from the sequential actuator, to rotate and select gears. This rotation can perform several actions at any time. Typically, the selector forks follow a track system that allows the selectors to follow a path that in predefined around the barrel.

Sequential Actuator

The sequential actuator is a key component of our sequential gear system. Its contains our unique rotary position sensor (BLADE 360º) along with a lock out system for neutral and reverse selection. This device is responsible for the transfer of motion in the system, in many PPG applications it converts a linear motion to a rotary motion…. Its rather clever! 

Straight Cut Gears

Straight cut tooth profiles in very simple terms is the angle of the gear tooth profile. Straight cut is associated with strength and noise in terms of the profile. Not all gear sets are made with straight cut in motorsports however, helical cut which is usually 12-20º degrees from parallel is the norm for OEM gear systems. We at PPG use helical in a lot of systems so as to provide a quieter profile which in turn makes the cabin more accommodating for endurance and road-based cars.

Helical Cut Gears

Helical cut tooth profiles are common in OEM applications inc DCT & DCT transmissions. The profile offers great contact area in larger gears and quiet operation for passenger comfort. We design a lot of our larger gear systems using helical tooth profiles as they offer large contact surfaces and quiet operational characteristics. They maintain good strength and longevity in service.

Gearbox GCU

The Gearbox ECU is a dedicated control system for gear shift parameters. Many motorsports ECU systems have integral GCU functionality to undertake the calibrations and controls in a single box solution. 


Many mid-market ECU systems do not have the ability to control closed loop gear functions, also paddle-shift controls are not covered. In this scenario a GCU can interface with the engine ECU and undertake the closed loop functions of sequential lever and paddle-shift gear systems, thus making it possible to retain existing chassis ECU systems without the need to reprogram and rewire. 


K.M.P – SHIFTEC – MEGALINE – GEARTRONICS all offer standalone GCU solutions.

Motorsports Wiring Harness

When building a motorsport chassis or fast road car there is a requirement to integrate new sensors, gearboxes, & ECU systems. This is overcome via the use of a custom wiring harness.


Theses types of harness' can be a full chassis loom or what is called an 'overlay loom'. When we supply a sequential gear system we supply a 'overlay loom' that is a generic design that will allow the customer to integrate our gear system and our sensors into their application. 

Motorsport wiring harness's use high quality connector and wiring, which offers increased performance in highly demanding environments containing heat, vibration and water.



Drive By Wire (DBW)

A mechanical linkage between the accelerator pedal and throttle butterfly has always existed, be it a cable or rod linkage. With modern ECU systems, theses manual systems have been replaced by sophisticated electronic control modules, sensors and actuators performing the task operated via control signals.


This system is also referred to as "Drive By Wire" or "Fly By Wire"

There are several reasons why electronic throttle actuation is preferable to a conventional throttle cable:

  • Chassis ECU systems are able to control all of the throttle operation.

  • The use of throttle actuation ensures that the engine only receives the correct amount of throttle opening for any give situation.

  • Allows optimised start procedures for traction & launch control strategies.

  • Closed loop gearbox shift management, throttle blipping, flat shift.

The use of such a system has advantages over the conventional cable version by:

  • Eliminating the mechanical element of a throttle cable and substituting it with fast responding electronics reduces the number of moving parts (and associated wear) and therefore requires minimum adjustment and maintenance.

  • Greater accuracy of data improves the performance of the chassis, which in turn provides better response, performance & repeatability.

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