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LED Treiber PCB

  • Manufacturer of a standard model of Driver PCB
  • Highly-durable range of Driver PCB
  • Bieten Sie Komponenten zu einem günstigen Preis an
  • Customizing  own design of Driver PCB

Was sind die Hauptmerkmale der Motortreiber-PCB?

Impressive features are the key factor of a Motortreiberplatine to be compatible with numerous
applications. Such as:
1.Low dielectric constant (below 4)
2.High decomposition temperature (more than 400°C)
”Maximum output current
3.Commendable heat dissipation rate
4.High glass transition temperature (more than 2809C)
5.High supply voltage

Key Features Of Motor Driver PCB
Wo wird die Motortreiber-PCB verwendet?

Wo wird die Motortreiber-PCB verwendet?

Motor driver PCB has brought out a new dimension in the following applications:
1.Autonomous robotics
2.Electric vehicles
4.Industrial sectors
5.Stepper motors

Was ist die beste Leiterbahnbreite der Motortreiber-PCB?

Normalerweise ist eine breitere Leiterbahnbreite der Motortreiber-PCB vorzuziehen. In den meisten PCB-Projekten können Sie Leiterbahnen mit einer Breite von mehr als 2 cm auftragen. Hier eine Formel zur Berechnung der Leiterbahnbreite für Sie.
Trace width, w=mils,Where, A= cross-sectional area of trace, T= thickness.

Was ist die beste Leiterbahnbreite der Motortreiber-PCB?

Your Best Driver PCB Partner


Venture is your best manufacturer of automotive and industrial products in China. We have the great kind of driver PCB and leading design engineers. Venture is a top market supplier of driver PCB in the electronics industry. Venture introduces designs, operations, and sales for our driver PCB supplies.

Venture can provide your driver PCB needs to support your projects. We offer this electronic device at affordable and friendly price.

Your Leading Driver PCB Supplier in China

Venture is an expert manufacturer of high-quality driver PCB for more than 10 years. Our driver PCB and other PCB products are manufactured using the latest technology and methods.

Als professioneller Hersteller stellen wir sicher, dass wir die beste Qualität unserer Produkte liefern, um Ihre Erwartungen und Anforderungen zu erfüllen.


If you are looking for a high-quality driver PCB, you are in the right place! Venture has been manufacturing high-quality driver PCB in different sizes and designs. We are offering an extensive range of driver PCBs to make sure that you will find your desired driver PCB.

Venture is an experienced manufacturer of driver PCB. This product has best features and enhance its usability and durability.


With our immediate response from our 24/7 sales and tech support team, we will be your best driver PCB partner in China. At Venture, we can answer any driver PCB questions that you may have. 


Our driver PCB is very useful in different application industry. This device can serve as L Series PCB LED drivers, LM Series PCB LED divers, V Series PCB LED drivers and DMX Bridges.

Wenn Sie weitere Informationen über Venture wünschen, können Sie uns eine E-Mail senden!

Driver PCB: The Ultimate FAQ Guide


If you have any question about driver PCB, you will find the answer right here.

It is because this guide explores all the fundamental aspect about driver PCB such as features, design, specification to material type.

Lesen Sie also weiter, um mehr zu erfahren.

What Is A Driver PCB?


A LED Driver PCB

A driver PCB allows you to operate another circuit or component by controlling the flow of current through the circuit.

Driver PCBs can produce high quantities of current and dissipate a significant amount of power.

This power usually dissipates in the copper regions of the driver printed circuit board. Special driver PCB design strategies are necessary to ensure proper cooling.

What Types Of Driver PCBs Can You Find?

You find the following types of driver PCBs:

AC Driver PCB

An AC driver PCB, like a DC drive, transforms alternating current into direct current. However, following this initial conversion, the DC reconverts into AC, which powers the motor.

AC Driver PCB

 AC Driver PCB

AC driver PCBs are principally amplifiers or frequency inverters that act as a link between an AC-Motor and a controller.

The driver transforms the controller’s inputs (step and direction) into the proper voltage, making the voltage harmonious with the motor.

DC Driver PCB

DC Driver PCB transforms AC (alternating current) to DC (direct current) in order to power a Gleichstrommotor.

The interface between a DC motor and a controller is provided by the DC driver PCB, which are power modules.

The controller integrates with the drive circuit, assisting in the powering of the control signals that interact with the drive.

A DC driver PCB typically features a pair of Siliziumgesteuerte Gleichrichter (SCRs).

These SCRs employ a single-phase AC input to generate a DC output with half-cycle. You refer to this power generation type as half-bridge method.

You employ three pairs of SCRS in more complicated and powerful DC drives to implement a full-bridge technique.

When using the full-bridge approach, the six SCRs generate the DC output using a three-phase AC input.

DC Driver PCB

DC Driver PCB

Servo Motor Driver PCB

A Servomotor driver PCB allows you to provide clear-cut movements to push or rotate your machine. The circuit transforms the input power through conversion of an alternating or continuous current source.

It converts this into a pulsed current output with varying pulse frequency and length. You can employ this driver circuit to control the torque, positions and motor speeds.

Fig 4- Servo Motor Driver PCB

Servo Motor Driver PCB

Stepper Driver PCB

A Schrittmotor driver PCB converts alternating or continuous current sources into stepped current output. It thereafter employs the output to change the input power of the stepper motor.

Stepper motor driver circuits employ permanent magnets in the detection and adjustment of input power. They also utilize cautiously spaced poles in the rotor and stator employing DC currents in the making stepwise rotation.

Fig 5 - Stepper Driver PCB

Stepper Driver PCB

Where Do You Employ Driver PCBs?

You find different applications of the driver PCBs with many employing similar operation that encompasses power application via current-carrying conductors. These include:


Linear motors produce forces in only one direction, employing permanent rare-earth magnets in generating magnetic flux. The flux interacts with the current in the conductors to generate mechanical force.

Fig 6 - Driver PCBs Employed As Linear Motors

Driver PCB Employed In Linear Motors

Linear motors have the ability to accelerate swiftly, position themselves precisely, and operate at high speeds. You find linear motors in applications requiring precise speeds due to their speed control.

Brushed And Brushless Motors

A brushed motor commutates and generates mechanical energy using physical contact. The motor’s brushes employs carbon or other materials as electrical contacts with the commutator when the shaft rotates.

The motor’s brushes, actually assist the DC power source in connecting to the rotor assembly. You find the rotor assembly includes the output shaft, armature and commutator rings.

Brushless motors, unlike brushed motors, do not require physical contact to initiate commutation. They don’t employ brushes to create motion, and instead use magnets to attract the stator’s powered coil windings.

Bürstenlose Motoren

Bürstenlose Motoren

The motor generates torque via electromagnetism as a result of its design. You can change the rotation speed of the motor by adjusting the direction and magnitude of the stator coils’ current.


To induce current into the rotor windings, induction motors don’t employ any mechanical connection with the stator windings. Induction motors create immense power, and possess variable speed control with high adaptation to a wide range of situations.

However, induction motors are prone to slide, which causes them to lose their precise speed tracking. Nevertheless, you find these motors in many regular applications such as household devices like kitchen appliances, air conditioners, and industrial machinery.


Servo motor driver PCBs find frequent use in robotics due to their small size. You find these driver circuits give the essential precision and force density for the proper functioning of robots.

Some of the robots that employ servo motor driver PCBs include those used in high-risk applications such as firefighting and bomb detonation. Additionally, you find robots in industrial production where they aid in moving materials or conducting processes like cutting and bending.

Sensor-less Vector Drives

A sensor-less vector drive independently regulates the frequency and voltage fed into the motor enhancing speed control and low-speed torque output. These drives don’t employ any feedback sensors like encoders and resolvers.

You can employ the sensor-less vector drives in various industrial applications. These include those with high inertia or when you require premium steady-state speed precision.


Fig 8- A Synchronous Motor With An AC Driver PCB

A Synchronous Motor With An AC Driver PCB

You find synchronous motors great where you need a reliable motor that maintains a constant speed. Even with a full load, these motors and their AC driver PCBs can maintain a precise speed.

A synchronous motor has no slip because the stator’s revolving magnetic field speed is equal to the rotor’s speed.

Synchronous motors are commonly employed in applications that demand extreme precision. You find these motors in high-precision drill machines where they are highly accurate.

What Are The Major Components In A Motor Driver PCB?

When furnishing a motor driver PCB, you find major components that cannot miss in the circuit structure. These include the controller, the motor and the power supply unit.

  • Regler: you can have a microprocessor or microcontroller for your motor driver PCB. The controller directs and enables processes of the circuit formation.
  • Motor: A motor is an electro-mechanical device that propagates movement. You have many types depending on the power employed to perpetuate motion such as AC or DC power.
  • Energieversorgung: The power supply unit provides the motor driver PCB the power to deliver to the motor.

What Role Does Copper Play On A Driver PCB?

The substrate material for driver PCBs such as FR-4 glass epoxy is a poor heat conductor. Contrarily, copper is a good heat conductor making a large copper area on a PCB ideal for heat control.

Thick copper conducts heat better than thin copper, however the former comes at a cost. Furthermore, using thick copper in making intricate designs of driver PCBs is difficult.

When you employ solid-copper planes, to your driver PCB’s internal layers, you can achieve incredible thermal management. However, the danger of their internal location is that they can cause heat entrapment.

Nonetheless, you can employ extra copper to the outer layers alongside interlayer connections known as vias to aid in heat transfer. Traces and components in a two-layer driver PCB can complicate heat distribution.

In this case, using solid copper with adequate thermal connections in the driver PCB will help ease the thermal burden. You can also employ copper pours alongside vias to spread the heat across areas sliced by traces and components.

Should You Use Wide Trace Widths On A Driver PCB?

You need to carefully consider the width of driver PCB traces because of the large current transmitted. Using wider traces allows you to lower the electrical transfer resistance of the driver PCB.

Trace resistance results in excess power dissipation in the form of heat, and you therefore need to size appropriately. Where you have a very small trace, it can function as a fuse and blow open.

The IPC-2221 standard guides designers in the determination of suitable trace sizes for your driver PCB. You find the standard provides a chart highlighting the cross-sectional copper area at different currents and the associated rise in temperature.

From the chart, you can derive the appropriate trace width for your driver PCB when using a particular copper thickness. For instance, using 1-oz copper to carry 10 amperes achieves a heat rise of 10°C with a 7 mm trace-width.

The trace-width guidelines in the IPC-2221 standard are for extended PCB traces with consistent width. Therefore, you can connect a short PCB trace to a larger one allowing larger currents to pass through without causing damage.

You credit this to the low resistance exhibited by the short, thin PCB trace. Consequently, any generated heat transfers to the larger copper sections, acting as a heat sink resulting in a small temperature rise.

The insulating substrate is a poor conductor of heat.

Therefore, the inner layer traces of the driver PCB cannot disperse heat efficiently as the external layers.

As a result, you need to make the inner-layer traces roughly twice the width of the external layers.

Routing with wider traces or copper sections will reduce temperature increase and voltage drop if space allows.

Can You Furnish Thermal Vias For Your Driver PCB?

Ja, du kannst.

Durchkontaktierungen are conductive holes that you use to carry a signal trace between layers.

Thermal vias share similar construction but instead of transmitting heat between layers, they convey heat.

Thermal vias are crucial for heat dissipation on a driver PCB, but there are various manufacturability aspects you need to consider.

Vias exhibit thermal resistance that you measure in degrees Celsius per watt. Here, you observe a temperature drop as heat travels through the vias.

You need large vias, with an extravagance of copper material to curb this resistance and make the vias more thermally effective. While you can employ large vias in the driver PCB’s open parts, using them within a pad area is more common.

Having vias within pads allows you to transfer heat directly from the integrated circuit package. Large vias aren’t possible in this instance due to solder wicking.

Solder wicking arises when the solder meant to link the IC to the driver PCB seeps down into the via. Consequently, it results in a weak solder bond.

When placing thermal vias within pad areas, consider the board components employing surface-mount-technology to determine the appropriate via size and construction.

Thermal reliefs should never be used for thermal vias, instead you need to connect them to the copper areas directly.

How Can You Prevent Solder Wicking In Your Driver PCB Thermal Vias?

You can reduce solder wicking in driver PCBs by many different ways as follows:

  • You can utilize minute via holes which reduces the amount of solder wicked into the holes. Nonetheless, small vias have high thermal resistance thus requiring more to extract similar thermal performance.
  • You can also tent the vias on the driver circuit board’s backside. This entails removing the solder mask’s rear aperture so that the material (solder-mask) conceals the via.

The solder mask will block the via, if small, preventing solder from wicking through the driver board. However, a major drawback of this is the possibility of flux entrapment inside a plugged through-hole.

Fig9- Removing The Solders Apertures AidsIn Preventing Solder Wicking

Removing The Solders Apertures Aids In Preventing Solder Wicking

Why Do You Need Solder Exposed Pads In Driver PCBs?

Underneath the component in TSSOP and QFN packaging is a huge exposed pad. You utilize this pad attached to the die’s reverse to dissipate heat from the component.

For efficient power dissipation, you need to make a good solder to the driver PCB.

A substantial volume of solder paste gets deposited if you employ a single aperture similar in size to the pad.

When the solder melts, the surface tension of the solder might cause the gadget to lift up.

You also need to consider solder voiding which is the creation of cavities or gaps inside solder areas.

During the process of solder reflow, the volatile constituent of flux boils up, causing solder voiding. Consequently, solder may be forced out of the joint as a result.

To solve these challenges, you put the paste in multiple small squares or circles for pads exceeding four square millimeters.

The volatile flux components can more easily evacuate the paste when you divide it into smaller sections, without supplanting the solder.

How Do You Place Components On A Driver PCB?

Fig 10-Pick And Place Method Of Placing Components In A PCB

Pick And Place Method Of Placing Components In A PCB

Driver PCB component placement rules are comparable to those for other types of circuit boards.

For instance you position bypass capacitors close to the device power pins in close proximity to the bulk capacitors.

Many driver PCBs employ bootstrap and/or charge-pump capacitors in close proximity. You typically route most of the signals on the topmost layer.

You employ a via system to transfer signals between bulk capacitors and bypass and charge pump capacitors at the bottom layer.

A flip-chip on lead frame architecture allows you to enhance leaded packages’ power-dissipation potential.

In absence of bond wires, you attach the die to the metal leads, employing copper bumps and solder. Doing this permits heat transfer from the die to the PCB via the leads.

What Component Attachment Techniques Can You Employ On A Driver PCB?

There are two common methods of attaching components on a driver PCB:

Durchgangsmontage (THM)

In Durchsteckmontage, you insert the component leads into drilled and plated holes on a bare driver PCB. Through-hole mounting serves you best where you need stronger component connection which enhances reliability.

You note that the through-hole component leads intersect the board, allowing them to resist environmental stress than SMT components.

Oberflächenmontagetechnologie (SMT)

Surface mount technology refers to the method of directly mounting components to the driver PCB’s surface. SMT, unlike THT, does not need you to drill holes into a driver PCB.

Furthermore, SMT components are much smaller and can be installed on both sides of the board. The ability to fit a large number of small components on a driver PCB has resulted to increased density and efficiency.

What Packages Can You Employ For The Driver PCB?

You can employ several different packages with your driver PCB including the following:

SOIC Packages

SOIC package is a standard IC packaging for the driver PCB. You can employ a flip-chip on lead frame architecture for your SOIC package to maximize its power dissipation capability.

When not using bond wires, you attach the silicon die to the conductive leads utilizing copper bumps and solder. This way, you can transfer heat from the die to the PCB via the leads.

Fig 11- A SOIC Package That You Can Choose For Your Driver PCB

A SOIC Package That You Can Choose For The Driver PCB

TSSOP Packages

TSSOP packages have two pin rows and are typically rectangular. The pins connect to the die via bonded wires between the chip and the lead frame.

You note that with this configuration, there is minimal heat transfer via the leads. TSSOP packages for driver PCBs typically include a vast exposed pad at the package base that aids in heat dissipation.

You require a well-soldered connection to the exposed pad to dissipate heat from this package type. Since you need a ground connection for this pad, you can link it to the ground plane of the driver PCB.

QFN Packages

QFN packages are without leads instead feature pads lining the edges with a massive pad at the center of the base. You extract heat from the die via this vast pad.

Wires linked between the chip and the lead frame connect the pads along the die’s periphery. You solder the exposed pad on the QFN’s package to the driver PCB to provide a channel for heat dissipation.

Fig 12- QFN Design That Can Be Used In Driver PCB

QFN Designs That Can Be Used In Driver PCB

What Noise Types Can You Experience On A Driver PCB?

Where your driver PCB employs analog circuitry, you are bound to experience some noise form. You find the following noise types possible:

  • Conducted Emissions: Includes the noise generated by analog circuitry as a result of its connections to other circuits. Unless it’s a high-power circuit, this is usually minor in analog circuits.
  • Conducted Susceptibility: External circuitry noise makes way into the analog circuit via its connections to other circuits. A ground or power connection, an input or an output, can all allow noise to enter the circuit.
  • Abgestrahlte Emissionen: Noise produced by analog equipment and transmitted across the air. Unless it’s a high-frequency circuit, this is usually also minor in analog circuits.
  • Radiated Susceptibility: Noise that comes from outside sources and transmitted through the air. Radio frequency interference is a result of high-speed clocks and switching digital signals.

How Many Layers Should A Driver PCB Have?

The number of layers in a driver PCB depends on the design complexity of the circuitry. You can furnish your board as single-sided board, a double-sided board or a multilayer board.


Single-sided driver PCBs employ a thin copper shell and substrate making the board relatively low cost. You employ several jumper wires in these designs to simulate the routing on a two-layer board.

You find this method only suitable for low-frequency circuits. Nonetheless, this architecture is vulnerable to radiated noise.


There are two copper films on double-sided boards making routing signals easier by crossing traces on separate levels. For analog circuits, however, you should not cross traces.

You need to route all other signals on the top layer, reserving the bottom layer for use as a ground plane.


Multilayer boards are preferable for sensitive driver PCBs with high-speed design. Having many layers allows adequate spacing decreasing distributed capacitance.

What Are The Benefits Of Having A Driver PCB With Multiple Layers?

Multi Layer PCB

Mehrlagige Leiterplatten

You find many advantages in furnishing a driver PCB in multi-layer configuration.  The following are some of the benefits:

  • Between the power and ground planes, you observe distributed capacitance, which reduces the occurrence of high frequency noise.
  • You have the options of employing serval signal routing layers, making the signal routing process easier.
  • You achieve power and ground connections with more efficient routing. You can share out a power plane throughout the circuitry by using vias.
  • The image plane effect occurs when you place a conductor adjacent to a parallel conductive surface. Here, the majority of the high frequency currents will flow in the other direction, straight under the conductor.
  • Because of the image plane effect, there is better EMI/RFI rejection in a multi-layer driver PCB.
  • For modest production runs, the overall project cost is low for multi-layer driver PCBs despite their costly manufacture.

You find EMI/RFI standards may necessitate expensive design testing. Where there are issues, you may need to redesign the driver PCB which will necessitate more testing hence costs.

What Are The Advantages Of Employing A Separate Ground Layer For Your Driver PCB?

You find the following advantages in employing a separate ground plane for your driver PCB:

  • The most common link in a circuit is the ground. For circuit routing, it’s usually best to keep it continuous on the layer at the bottom.
  • It improves the driver circuit board’s mechanical strength.
  • Using a separate ground plane decreases all ground connections’ impedance, thereby reducing unwanted conducted noise.
  • Every net in the circuit gains a distributed capacitance, which helps to reduce radiated noise.
  • It works as a buffer against transmitted noise from beneath the board.

How Do You Stack-Up A Driver PCB?

There has always been a debate about the best order for PCB layers. Consider a four-layer board with a pair of signal layers, a power and ground plane.

The question usually is, is it better to route signal traces across layers, offering shielding? Or to furnish the ground and power planes as the inner layer plane pairing?

When examining this question, note that regardless of the decision made, you’ll have exposed signals on the top and/or bottom planes. The traces leading to surrounding passive components and feed-throughs, as well as package leads will be exposed.

Consequently, you harm any shielding effects. Making the power and ground planes internal allows you to capitalize on the dispersed capacitance between them.

Positioning the ground and power internally makes the signal planes on the outer layers easily accessible for probing and adjustment. Where you have more than four layers, shield high-speed communications between the ground and power with slower signals external.

What Grounding Rules Do You Apply In A Driver PCB?

When providing grounding for your driver PCB, the following guidelines are recommended:

  • Grounding is a design consideration at the system level which you should include in the design from conceptualization.
  • Don’t let the digital and analog planes overlap, instead connect the power and grounds of the analog and digital planes respectively.
  • You can suppress noise by separating the analog and digital sections of the driver circuitry.
  • Separating the grounds doesn’t imply electrical separation of the grounds in the system. Rather, you should link them via a system ground through a single point of low-impedance.
  • Decoupling capacitors and distributed capacitance ensure similar AC potential for the ground and power planes. As a result, it’s critical to separate the power planes.
  • Employ independent connector pins for separate returns where possible only combining the returns at system ground.
  • Keep digital signals separate from analog circuitry positioning the latter close to the board’s input/output connections.

Why Is Input And Output Isolation Important In Driver PCBs?

Noise manifests in the circuit through the input and output pins causing many difficulties. The driver circuit’s reaction to high-frequency noise may be capricious due to the passive components’ high-frequency limitations.

Sometimes conducted noise has a frequency significantly different from the circuit’s typical operating range. In this case, all you need is a passive filter (RC low-pass) that discards RF frequencies with inconsequential audio frequencies influence.

Consider, RF noise routed into an audio op amp circuit. In this case, a low pass filter exhausts its properties requiring many stages to span different frequency ranges.

Here, you need to furnish the highest frequency filter closest to the noise source. You can also employ ferrite beads or inductors in a filter network for rejecting noise to eliminate conducted noise.

Until you attain a particular frequency, you note that ferrite beads are inductive before becoming resistive. Sometimes you experience severe radiated energy coupling effect into analog circuitry ultimately requiring shielding.

You can employ a Faraday Cage with an intricate design that prevents problem frequencies from entering the circuit. The cage should have no openings greater than th of the problem frequency’s wavelength.

Achieving this can be difficult and it is better to include the shield in your initial PCB design before commencing construction. Using a shield exacerbates the problem requiring the use of ferrite beads on all circuit connections.

For all your driver PCB, contact Venture.

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