Audio in Smart glasses
Optimized using advanced simulation and measurement tools
Compared to earphones and headsets, which are positioned in the ear canal or directly onto the ear, the loudspeakers in smart glasses are situated in a so called near field related to the ear entrance. Therefore the tuning of the acoustic parameters are quite different from ear- and headphones, both in repects of desired frequency response and loudness. The acoustic impedance “seen” by a near field driver is very different from the in-ear impedance, which is why it takes much larger driver to produce a satisfying bass response compared to sealed earphones.
The tuning has to account for reflections coming from the head as well as low frequency cancellation caused by sound waves from the rear side of the loudspeaker’s diaphragm that can reach the ear through a rear vent. Such rear vent can be necessary if there is not enough space in the temples for a large enough air volume behind the speaker to allow for a decent bass content, but the placement of the vent is critical to avoid cancellations. Using simulations various port placements can be tested without the need for physical prototypes.
Ole Wolff uses a model of a dummy head and a detailed human ear similar to Head & Torso simulators found in our labs.
Typically the driver is modelled using Thiele-Small parameters to keep computation time down but full mechanical models can also be used.
The air volumes surrounding the driver and the holes, leakages and meshes to the outside world are modelled and so is skin- and eardrum impedance of the head.
Using a virtual model allows for trying different speakers by changing the associated speaker parameters. This can speed up the development process considerably compared to building physical prototypes.
Example of Thiele-Small data of a 8x15mm speaker used in a pair of glasses with a built-in speaker.
A head and torso simulator (HATS) is being used to measure the acoustic performance of the speaker glasses.
A satisfying acoustic performance is always the ultimate goal. Objective performance is tested using a head and torso simulator (HATS) and subjective performance is evaluated by both the end customer and our engineers.
When designing a pair of smart glasses it is tempting to choose as small a driver as possible to keep the overall thickness of the temples down. However, the laws of physics still apply no matter how smart the smart glasses are. In order to get as much “bass” frequencies as possible, a certain volume of air must be moved which, in general, correlates with both the diameter and the thickness of the chosen driver. Other important parameters to consider are:
The OWR-1653T-20 driver is an excellent driver with good compromise between size and performance that will work well in applications such as smart glasses.