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How a Planar Magnetic Diaphragm Headphone Driver Works

Typically, dynamic drivers feature a voice coil attached to the middle of the diaphragm conical. When electrical signals pass through the voice coil it causes the diaphragm to move.

However, the force exerted is limited to a narrow area, making it difficult to allow different parts of the diaphragms to move at the same at the same time. This leads to breakup modes that can lead to distortion.

Sound Detail

Many audiophiles are looking to get an authentic sound from their headphones. This can be accomplished with a planar diaphragm. This kind of headphone driver operates similarly to dynamic cone drivers however with more modern technology behind it.

A planar diaphragm is an elongated structure placed inside the frame of a headphone and made of a thin and light material. It's designed to be as homogeneous as possible, and its flat surface permits an even distribution of pressure across the entire surface which, in turn, improves sound clarity.

A flat planar magnetic diaphragm's design allows for a better soundstage. A more focused soundstage is made possible by a narrower wavefront. This helps pinpoint where an instrument or vocal is situated on the track. This is a major benefit over the more spherical waves typical of dynamic drivers.

A planar diaphragm is different from traditional dynamic drivers that utilize a voice coil that is attached to the center of a cone composed of plastic or paper. Instead, it uses a series of magnets on each side of its flat surface. The diaphragm vibrates and creates sound when the electrical current that flows through the voice coil interacts with the magnets. The entire diaphragm is controlled simultaneously. This removes breakup modes, mechanical filters, transmission delays and local resonances that could have a negative impact on the sound quality.

A diaphragm that is flat and uniform can also accelerate more quickly than the thicker and heavier ones used in dynamic drivers. According to the laws of physics, force is proportional mass and acceleration. This means that the faster a driver's diaphragm moves the more power they are able to exert. This results in planar magnetic drivers more precise bass response and greater detail retrieval.

The advantages of a planar magnetic driver are not without cost. They're more expensive than dynamic drivers since they feature a huge diaphragm and a complicated motor. They also require a larger amplifier to work properly. Many planar magnetic headphone makers benefit from their technology and create premium headphones at competitive prices. Audeze LCD-4, HiFiMAN Susvara are a few examples.

High Sensitivity

Planar drivers differ from moving coil drivers that are used in the majority of headphones or IEMs in that they employ a flat membrane instead of a conventional cone or dome membrane. As an electrical signal passes, it interacts both with the magnets as well as the diaphragm, generating sound waves. The flat diaphragm can react quickly to sound, and can produce a wide range in frequencies from lows to highs.

Planar magnetic headphones are more sensitive than other drivers for headphone, which can use diaphragms up to multiple times larger than a standard planar design. This lets you hear all the details in your music.

Planar magnetic drivers also produce an extremely consistent driving force throughout the diaphragm. This reduces breakup and creates a smooth, distortion-free sound. This is particularly crucial for high frequencies where the sound's breakups can be quite loud and distracting. In the FT5 the way this is achieved is by using an advanced material called polyimide. It is both ultra-light and extremely robust, as well as a specialized conductor pattern that eliminates the inductance related intermodulation distortion.

OPPO's planar magnetic drivers also have better phase coherence, which means that when a wavefront enters the ear canal, it's an unaltered and flat shape. Dynamic drivers, on the other hand are spherical in their wavefront that disrupts the coherence, planar magnetic headphone resulting in less-than-perfect signal peak reconstructions, especially in high frequencies. OPPO headphones sound extremely natural and authentic.

Wide Frequency Response

Planar magnetic diaphragms have the ability to reproduce sounds at much higher frequencies than traditional dynamic drivers. This is due to their diaphragm is thin and light in weight. moves very precisely. This enables them to deliver an excellent transient response. This makes them a perfect choice for audiophiles that require rapid responses from their headphones and speakers to reproduce the finest details in music.

This flat structure also provides them with an even soundstage than regular headphones that use dynamic drivers that are coiled. They are also less susceptible to leakage - sound that escapes from headphones and into the environment. In some cases, this is a problem because it can distract listeners and disrupt their concentration while listening to music. In some instances, this can be a problem since it can distract listeners and alter their focus while listening to music.

Rather than using a coil behind a cone-shaped diaphragm planar magnetic headphones feature an array of conductors printed on the extremely thin diaphragm itself. The conductor is hung between two magnets. When an electrical signal is applied to it, it becomes electromagnetic and causes the magnetic forces on the opposite side of the diaphragm to interact with each other. This is what causes the diaphragm to vibrate and produce a soundwave.

The uniform motion of the diaphragm that is light and the fact that the force is evenly distributed across its surface which means distortion is extremely low. This is a major improvement over traditional dynamic drivers that can cause distortion when listening to high volumes.

Certain high-end headphones employ the old-fashioned design of moving coils. However, planar magnetic Headphone the majority of HiFi audiophiles are now embracing this old technology to create new generation planar closed back headphones magnetic headphones that produce a stunning sound. Some of these headphones are extremely expensive and require a premium amplifier to power them, but for those who can afford them they offer an amazing experience that is unmatched by any other headphone. They have a deep clear, clear sound that's free of distortion that can be found in other types of headphone.

Minimal Inertia

As a result of their construction the planar magnetic diaphragms are extremely light and can move much faster than traditional drivers. This means they can reproduce audio signals with greater precision and can be tuned to greater frequency ranges. They also produce an authentic sound and have less distortion than traditional dynamic speakers.

The dual rows of magnets in a planar driver produce equal and uniform magnetic forces across the entire surface of the diaphragm. This reduces unnecessary and unwanted distortion. Because the force on the diaphragm's light weight is distributed evenly, it can be controlled more precisely. This allows the diaphragm vibrate with a precise pistonic movement.

Planar magnetic drivers are capable of achieving extremely high levels of performance while carrying a minimal weight, making them ideal for portable headphones. They can also be produced to have an array of frequencies, from deep bass to high-frequency sounds. The wide frequency response and accurate sound reproduction make them a favorite for audio professionals.

Unlike dynamic drivers, which utilize coils to push against the diaphragm the planar magnetic driver has no mechanical parts that can come into contact with one other and cause distortion. This is because the flat array sits directly on top of the diaphragm rather than being in a coil behind.

A planar magnetic driver, however it can drive a small and light diaphragm by applying a tremendous magnetic force without any energy loss. The diaphragm, an extremely thin and lightweight membrane is driven by an electric field that creates an unchanging pressure. This stops it from deforming or causing distortion.

The moment of inertia is a crucial property that describes an object's resistance to rotation. It can be calculated from the formula I = mr2. The shape of the object determines its moment of inertia minimum. Thicker and longer objects have lower moments of inertia.