Types of Haptic Feedback and How They're Used – Boréas Technologies (2024)

Haptic feedback technology allows users to receive information through their body, providing an embedded bodily sensation that transmits critical information about the system the user is engaging with. Mobile phones, for instance, vibrate to alert their owner that they've received a message. This vibration is a type of haptic feedback. Haptic feedback can augment auditory and visual feedback and enhance the user experience.

Haptic Feedback Categories

Haptic systems provide two types of haptic feedback: kinesthetic feedback, simulating the weight or pressure of an object, or tactile feedback, which simulates texture.

Kinesthetic Feedback Systems

Kinesthetic feedback systems simulate the weight or pressure of an object. For instance, in a driving video game, the steering wheel may resist turning when moving at higher speeds or operating a heavier vehicle. This type of feedback directly impacts the muscles of the user. In the driving game example, the user has to apply more force to get the desired response from the steering wheel.

Biomimetic and Non-biomimetic Kinesthetic Feedback Systems

There are two large categories of kinesthetic feedback systems: biomimetic and non-biomimetic. Biomimetic devices mimic biological forms, usually the human body. Biomimetic devices include cybernetic limbs designed to mimic the human body's response as closely as possible to grant amputees standard sensation and functionality. Non-biomimetic devices don't have to imitate the human body and have a wider variety of forms and applications.

Resistive and Active Kinesthetic Feedback Systems

Force feedback devices may be further divided into resistive appliances and active appliances. Resistive devices only restrict movement — like the steering wheel in the video game example — while active devices utilize motors to compel the body to move. Active devices can simulate many movements but must be actively powered, whereas resistive devices can often operate passively. Active systems are also significantly more complex than passive systems, making them harder to design, manufacture, and use.

Tactile Feedback Systems

Tactile feedback systems stimulate the user's sense of touch. We've already talked about tactile haptic feedback systems that use vibration (also called vibrotactile feedback), but tactile haptic feedback can also include electrical signals, air pressure, and sound waves. Two common special types of sensory feedback are facilitated through a haptic interface:

Electrotactile Feedback Systems

Electrotactile feedback uses electrical impulses to provide haptic stimulation to nerve endings in the user's skin. Electrotactile feedback can create highly realistic experiences for users wearing suits or gloves equipped with electrotactile technology. Almost any sensation can be simulated with electric pulses: temperature changes, pressure changes, a sense of moisture. Electrotactile systems empower a level of technological immersion not previously possible.

Ultrasound Tactile Feedback Systems

Ultrasound tactile feedback uses high-frequency sound waves to simulate sensations within an environment. Two or more emitters send ultrasound to one another to create a haptic feedback field, creating sensations in users who simply walk through the field. Ultrasound tactile feedback does not require those experiencing the haptic feedback to wear devices themselves. However, it's more expensive and creates a less vivid experience than its vibrotactile and electrotactile counterparts.

Sensory Feedback Applications in Haptic Technology

While a raw description of haptic feedback systems is certainly interesting, haptic technology applications may not be immediately apparent, particularly when thinking of haptics as an abstract, aesthetic experience. However, haptic feedback systems are much more than a novelty; they open up an entirely new communication channel between a device and its user. We already transmit information through sight and sound, but creating corresponding sensations for each cue deeply enriches a user's experience. Here are a few applications of haptic feedback technology:

Immersive Experiences in Gaming Devices and Displays

Haptics have been in gaming since the 1990s. Any rumble functionality on a controller, no matter how primitive, is an example of haptic feedback. However, these haptic responses have become more and more nuanced, with different vibrations alerting gamers to different kinds of in-game events.

Touchscreens have now largely replaced controllers, especially for casual gamers. Touch screenswith haptic feedback have bridged the sensory gap between static, physical controllers and their touch-sensitive counterparts. Tactile displays equipped with haptic feedback may not sit in every living room yet, but most smartphones have haptic displays — some more capable than others.

Even less hardware-intensiveuser interfaces can dramatically impact player experience. For example, trackpadsand micethat provide haptic feedback to users can simulate resistance and vibrate according to in-game action, supplying the player with more information. Similarly, haptic stylusescan enhance the textural experiences of artists, bridging the experiential gap between crafting in physical and digital mediums.

Interactions Through Tactile Sensors on Wearable Haptic Devices

With the rise of virtual reality (VR) gaming and specialized hardware, haptics are poised to play a more central role in the gaming industry. Haptic suits outfitted with wearable piezos can immersively simulate otherworldly environments and sensations for players, transporting them directly into the game world. Electrotactile and vibrotactile feedback systems, particularly, are well-suited to this task.

Creation of Intuitive Robotic Devices and Computer Technology

Human reflexes are closely tied to our haptic perception, and stimulating tactile perception can encourage humans to react appropriately to changing situations. Haptic feedback can also transmit familiar situations across distances, permitting more measured responses in situations that might lead to a sudden or jerky movement.

This type of intuitive robotic assistance may completely revolutionize surgery. Surgeons already use tactile feedback heavily to aid in their decision-making process. Sometimes tissues present with abnormal texture or firmness, necessitating a sudden change in course on the surgeon's part. Surgeons using robotic systems that lack haptic feedback are losing out on all of the information otherwise transmitted to them by their sense of touch. Outfitting robotic surgical equipment with haptic feedback reopens an old multimodal feedback channel that surgeons rely on to make good decisions and carry out successful operations.

Responsive Haptic Feedback Technology Starts With a Quality Piezo Driver

The most practical method of generating haptic feedback is using a piezoelectric solution, including a piezo transducer and piezo driver. Boreas Technologies offers piezo haptic drivers suitable for most applications, boasting low power consumption, high energy recovery, and substantial throughput to drive powerful transducers. Our drivers, powered by CapDrive Technologycircuit architecture, are 10 times as energy-efficient as conventional piezo drivers, offering the lowest power consumption in the industry. Learn more here.