I measured the B200s using a G.R.A.S. RA0045 coupler (with a Model 43AG ear/cheek simulator used for isolation measurements), a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, and a Musical Fidelity V-Can headphone amplifier. I used the supplied medium-size silicone eartips, which best fit the RA0045. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The B200s’ measured performance is a little flatter than average for earphones, though that doesn’t necessarily mean they’ll sound flatter. Relative to the peak at 2.4kHz, the output above 5kHz is a little lower than I’m used to seeing, which suggests that the B200s won’t sound bright.
This chart shows the results of adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amp. Balanced-armature earphones usually show an audible difference on this test, but this result is comparatively extreme; using a source with a high output impedance -- such as the headphone amps built into many laptops -- will result in a much brighter sound.
This chart shows the B200s’ measured right-channel frequency response compared with those of three other earphones using balanced armatures or a combination of balanced armatures and dynamic drivers: 1More Quad Driver, Audiofly AF1120, and PSB M4U 4. The B200s measure roughly as flat as the AF1120s; this test suggests that the AF1120s will sound moderately brighter than the B200s.
Despite the B200s’ lightweight plastic enclosures, the spectral-decay (waterfall) chart shows no noteworthy resonances above about 300Hz, and less bass resonance than I often see in similar earphones.
The B200s’ total harmonic distortion (THD) is insignificant, maxing out at just over 1% at 20Hz at the extremely loud level of 100dBA.
In this chart, the external noise level is 75dB SPL; the numbers below that indicate the B200s’ degree of attenuation of outside sounds. For comparison, I’ve included the isolation plots of three other earphones: the Audiofly AF1120 (with over-ear cable routing), the 1More Quad Driver (with standard cable routing), and the Bose QC20, a model with active noise canceling that has the best performance I’d previously measured on this test. If memory serves, the B200s’ is the best measured result on this test that I’ve gotten from passive earphones -- in fact, I had to move the bottom of the measurement scale down to 20dB SPL to make the B200s’ result visible. According to this test, at least, the B200 won’t quite match the state-of-the-art Bose QC20 in the “airliner-cabin band” of about 100Hz to 1kHz, but it should do an even better job of blocking the noise of the ventilation system, crying babies, etc. Of course, isolation heavily depends on how well the eartips fit your ear canals; my subjective results weren’t so impressive because the largest of the Brainwavz’ included tips didn’t perfectly fit my ears. As always with earphones, your mileage may vary.
Like most headphones employing balanced-armature drivers, the B200s show a large impedance swing: about 15 ohms up to 300Hz, then rising to a peak of 145 ohms at 7kHz. The electrical phase doesn’t swing as radically, but it still varies quite a lot, from +45 to -38 degrees. This isn’t unexpected, given the B200s’ driver configuration, but it does mean that switching from a source with a low output impedance to one with a relatively high output impedance will change the sound significantly.
The B200s’ sensitivity, measured between 300Hz and 3kHz with a 1mW signal, is 116.1dB calculated for the specified 30-ohms impedance. This means that the B200s will play at a very loud volume from any conventional source device, even a $20 MP3 player.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the Quad Drivers using a G.R.A.S. Model RA0045 ear simulator (plus a Model 43AG ear/cheek simulator for isolation measurements), a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, and a Musical Fidelity V-Can headphone amplifier. I used one of the smaller silicone eartips because that’s what best fit the RA0045. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
Although the Quad Drivers’ frequency response might look a little bumpy, this is actually a fairly by-the-book earphone response -- the kind of response that’s generally thought to deliver subjectively flat sound. The only thing that’s slightly anomalous is that the 3kHz peak, a typical characteristic in measured earphone response, extends to higher frequencies than usual, up to about 5kHz. To attempt to confirm the Quad Drivers’ Hi-Res Audio certification, I set the Clio FW 10 for a 96kHz sampling rate instead of the usual 48kHz, to see how the Quad Drivers’ ultrasonic response compared to those of a few other earphones I had on hand -- and the 1Mores do seem to deliver a substantial amount of energy at 40kHz.
Adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amp, shows how the Quad Drivers differ from most balanced-armature earphones, many of which show radically varying responses on this test because of their large impedance swings in the treble. There’s almost no difference here at all -- just a boost of about 1dB above 10kHz. This leads me to speculate that the Quad Drivers use their dynamic drivers for all of the bass and midrange and even the lower part of the treble, and restrict their balanced armatures to the mid and upper treble. But you can’t argue with success.
This chart shows the Quad Drivers’ frequency response compared with some other multidriver earphone models: the Audiofly AF1120, the PSB M4U 4, and 1More’s Triple Driver. While the Quad Drivers aren’t as flat in measured response as the AF1120s, their response is more typical of what’s considered subjectively pleasing in earphones. Note that the Triple Drivers have more bass and treble output relative to their midrange.
The Quad Drivers’ spectral-decay (waterfall) chart shows no noteworthy resonances, and the resonance in the bass is somewhat less than I’m used to seeing with high-quality earphones.
The Quad Drivers’ total harmonic distortion (THD) is insignificant even at very loud listening levels. Even at 100dBA (measured with pink noise), distortion is only about 2.3% at 20Hz, which will be inaudible.
In this chart, the external noise level is 75dB SPL; the numbers below that indicate the degree of attenuation of outside sounds. For comparison, I’ve also included the isolation plots of: the Audiofly AF1120s, a model with over-ear cable routing, which tends to produce better isolation; the Sony XBA-H1s, which, like the Quad Drivers, use standard cable routing; and the noise-canceling Bose QC20s, which offer the best isolation of any earphones I’ve measured. The Quad Drivers deliver measured isolation that’s OK, but somewhat below average for earphones, though I didn’t notice a lack of isolation when wearing them. As always with earphones, your results may vary.
Most earphones with balanced-armature drivers show a huge impedance swing in the treble. The Quad Drivers don’t -- they’re almost dead flat at 31 ohms up to about 8kHz, and drop to about 23 ohms at 20kHz. The electrical phase is also surprisingly flat. This is why the Quad Drivers’ frequency response remains consistent, even when they’re used with amps with a high output impedance.
The sensitivity of the Quad Drivers, measured between 300Hz and 3kHz with a 1mW signal calculated for the rated 32 ohms impedance, is 107.6dB. That’s above average -- any source device will easily drive these earphones to high levels.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the P9 Signatures using a G.R.A.S. Model 43AG ear/cheek simulator, a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, a Musical Fidelity V-Can headphone amplifier, and an Audio-gd NFB-1AMP amplifier for distortion measurements. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The elephant in the measuring room is the P9s’ wide, deep dip centered at 550Hz. If that dip were about 6dB less deep, it would be pretty close to what I’d call a textbook headphone frequency response. What does that mean in terms of sound? I hate to predict headphones’ sound based only on their measured frequency response, but that big dip sure won’t make voices sound more prominent.
This chart shows the results of adding 70 ohms output impedance to the V-Can’s 5-ohm output impedance, to simulate the effects of using a typical low-quality headphone amplifier. Using the higher-impedance source boosts the bass by a maximum 1.5dB, which will result in only a subtle difference in the sound.
This chart compares the P9s’ measured right-channel frequency response with those of two other high-quality closed-back headphones (Oppo’s PM-3s and B&W’s own P7s) as well as Audeze’s LCD-X open-back headphones, the last used as the comparison standard in the review. The fact that the P9s’ big midrange dip is centered very close to 500Hz -- the reference frequency for this measurement -- makes the P9s look more different than they really are from the others. Still, the P9s will likely sound the most different of the four.
The spectral-decay (waterfall) chart shows a narrow but strong resonance at 1kHz that might occasionally be audible, depending on what you’re listening to. There are also resonances at 2.8 and 3.6kHz, but they’re so narrow and low in magnitude that it’s hard to imagine they’d be audible.
The P9s’ total harmonic distortion (THD) is low for dynamic over-ear headphones, maxing out at 1% at 20Hz at 90dBA and 3% at 100dBA -- and 100dBA is extremely loud.
In this chart, the external noise level is 75dB SPL; the numbers below that indicate the degree of attenuation of outside sounds. For comparison, I’ve included the isolation plots of other closed-back over-ear headphones: B&W’s P7s and Oppo’s PM-3s, plus Bose’s noise-canceling QC25s. The P9s’ isolation is about average, or maybe slightly above average, for this type of headphone.
Except at their impedance peak at 55Hz, the P9s average about 30 ohms impedance. Electrical phase is nearly flat.
The P9s’ sensitivity, measured between 300Hz and 3kHz with a 1mW signal, is 100.1dB, calculated for the specified 22 ohms impedance -- about average for closed-back headphones. In practical terms, this means that they’ll play at satisfyingly loud volumes with a Samsung Galaxy smartphone, and at very loud volumes with an iPhone.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the Amiron Homes using a G.R.A.S. Model 43AG ear/cheek simulator, a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, a Musical Fidelity V-Can headphone amplifier, and an Audio-gd NFB-1AMP amplifier for distortion measurements. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The Amiron Homes’ frequency response is a little unusual. Typically we see a strong peak in the region of 2.5kHz, then one or two weaker peaks at higher frequencies. In the Amiron Homes, the peak centered at 7.5kHz is by far the strongest. I can’t recall seeing a response quite like this before, so I can’t speculate as to what its subjective effects might be.
Adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amp, boosts the Amiron Homes’ bass by about 1dB.
This chart shows the Amiron Homes’ measured frequency response compared with those of the HiFiMan HE560s (a similarly priced planar-magnetic open-back model) and the NAD Viso HP50s, my comparison standard for midpriced closed-back headphones. Except for that strong peak at 7.5kHz, the Amirons seem within the norm for headphone frequency response.
The spectral-decay (waterfall) chart indicates that the Amiron Homes have almost no resonances. What few there are are well damped and die out within a few milliseconds.
The total harmonic distortion (THD) of the Amiron Homes is negligible at 90dBA, almost nonexistent above 60Hz, and rises to just 3% at 20Hz. At the extremely loud level of 100dBA, the THD is comparably low above 60Hz but rises to 9% at 20Hz.
In this chart, the external noise level is 75dB SPL, and the numbers below that indicate the degree of attenuation of outside sounds. For comparison, I’ve included the isolation plots of the open-back HiFiMan HE560s, the closed-back NAD Viso HP50s, and the noise-canceling Bose QC25s. The Amiron Homes provide above-average isolation for open-back headphones -- nothing below 1kHz, but they decrease environmental noise by 11 to 17dB at frequencies above 2kHz.
Through most of the audioband, the Amiron Homes’ impedance is closer to 300 ohms than the specified 250 ohms, and rises to a peak of 690 ohms at 95Hz. There’s some mild phase shift on either side of that peak, but the impedance phase is relatively flat overall.
The Amiron Homes’ sensitivity, measured between 300Hz and 3kHz with a 1mW signal calculated for the specified 250 ohms impedance, is 102.4dB -- high enough for a typical smartphone to be able to drive the Amiron Homes to loud levels.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the AF1120s using a G.R.A.S. Model RA0045 ear simulator (plus a Model 43AG ear/cheek simulator for isolation measurements), a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, and a Musical Fidelity V-Can headphone amplifier. I used a medium-size Comply foam tip because it fit the RA0045 best. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The AF1120s’ frequency response is unusually flat for earphones. Most earphones have more boost in the bass, and a fairly large response peak around 3kHz. In this case, however, flatter isn’t necessarily better. It’s generally considered best for earphones to have a somewhat stronger bass response and a stronger peak in the lower treble, which is thought to make them sound more like actual speakers in a room.
Adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amp, does affect the AF1120s’ tonal balance. This suggests that it would be unwise to use the AF1120s with a low-quality, high-output-impedance headphone amp, such as those built into typical laptop computers. With a high-impedance source (i.e., greater than 40 ohms or so), the AF1120s will likely sound too trebly. This relatively large difference in frequency response with high-impedance sources is typical for earphones using balanced-armature drivers.
This chart shows the AF1120s’ frequency response compared with two similar models, the PSB M4U 4s and the Optoma NuForce HEM8s. Notice how unusually flat the AF1120s’ response is. My subjective impressions were that the M4U 4s sound slightly trebly, while the HEM8s have a somewhat soft-sounding treble.
Despite the AF1120s’ no-frills plastic housings, their spectral decay (waterfall) chart is extremely clean, indicating no noteworthy resonances.
The total harmonic distortion (THD) of the AF1120s is insignificant at 90dBA, which is a pretty loud listening level. At the extremely loud level of 100dBA, the distortion rises to about 3% below 2kHz; that’s slightly on the high side, but if you listen long at this level you won’t have much hearing left anyway.
In this chart, the external noise level is 75dB SPL; the numbers below that indicate the degree of attenuation of outside sounds. For comparison with the AF1120s, I’ve included the isolation plots of two similarly designed passive earphones, the PSB M4U 4s and the Optoma NuForce HEM8s, as well as the Bose QC20s, the last offering the best isolation of any earphones I’ve measured. The AF1120s deliver an average level of isolation for earphones with over-ear cable routing, which is to say an above-average level of isolation compared with other earphones and most over- and on-ear headphones.
Like most earphones using balanced-armature drivers, the AF1120s exhibit a large impedance swing in the treble. It rises from the specified 10 ohms at 100Hz to a peak of 42 ohms at 8.9kHz. The impedance phase also shows large swings throughout most of the audioband.
The sensitivity of the AF1120s, measured between 300Hz and 3kHz with a 1mW signal calculated for the rated 10 ohms impedance, is 109.8dB. That’s above average, which means that any source device should be able to drive these earphones to loud levels.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the HE1000 V2s using a G.R.A.S. Model 43AG ear/cheek simulator, a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, a Musical Fidelity V-Can headphone amplifier, and an Audio-gd NFB-1AMP amplifier for distortion measurements. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The HE1000 V2s’ frequency response is about par for the course for headphones of this type, with flat response below 1kHz and strong treble response between 2 and 10kHz.
Adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amp, doesn’t affect the HE1000 V2s’ tonal balance. Still, a low-quality headphone amp may not deliver satisfying volume from the HE1000 V2s.
This chart shows the HE1000 V2s’ measured treble response compared with the original HE1000s and the Audeze LCD-Xes, another set of well-regarded, high-end, open-back headphones. The HE1000 V2s are similar to the original model, but with more treble response between 5 and 8kHz.
This spectral-decay (waterfall) chart indicates that the HE1000 V2s have the “Portuguese man-of-war” plot produced by many large planar-magnetic headphones, with many extremely high-Q (narrowband) resonances, as well as a fairly high-magnitude resonance centered at 5kHz.
The total harmonic distortion (THD) of the HE1000 V2s, measured with pink noise, is practically nonexistent: just 1% at 20Hz, even at the extremely high test level of 100dBA.
In this chart, the external noise level is 75dB SPL; the numbers below that indicate the degree of attenuation of outside sounds. For comparison, I’ve included the isolation plots of the original HE1000s, the Audeze LCD-Xes, and the NAD Viso HP50s, which are midpriced, closed-back headphones. As usual, the open-back models offer almost no isolation from outside sounds.
The HE1000 V2s’ impedance is almost dead flat at 35 ohms; their impedance phase response is also flat.
The sensitivity of the HE1000 V2s, measured between 300Hz and 3kHz with a 1mW signal calculated for the specified 35 ohms impedance, is 86.9dB. That’s very low; consider a decent headphone amp with at least 6dB more output than an iPhone essential to get the best performance from these headphones.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the second-generation T 5 p headphones using a G.R.A.S. Model 43AG ear/cheek simulator, a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, and a Musical Fidelity V-CAN headphone amplifier. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
Although the frequency response of the T 5 p headphones looks somewhat uneven, the measurement suggests a fairly flat overall tonal balance, with a little extra energy around 8kHz -- which is probably why I perceived the sound as being slightly bright.
Adding 70 ohms output impedance to the V-Can’s 5 ohms to simulate the effects of using a typical low-quality headphone amp shows that the T 5 p’s are only subtly sensitive to the source impedance, with a boost of about 1dB in the bass and treble response reduced by about 0.5dB. Thus, with a high-impedance source, the T 5 p should sound slightly warmer.
This chart of the Beyerdynamics’ measured treble response is more or less within the ballpark for high-end headphones. However, their bass response appears to be stronger than average for audiophile headphones -- stronger than Audeze’s closed-back, planar-magnetic LCD-XCs, or Sennheiser’s open-back, dynamic-driver HD 800 Ses.
The spectral decay (waterfall) plot of the Beyerdynamics is fairly clean, with just one pretty well-damped resonance at 8kHz (this corresponds with the response peak at that frequency), and less bass resonance than I usually measure in closed-back ’phones.
The total harmonic distortion (THD) of the T 5 p’s is low, evident only in the bottom octave of bass and only at high listening levels. Note that most of the distortion harmonics remain within the bass range; e.g., the fifth harmonic of 30Hz is 150Hz.
In this chart, the level of external noise is 75dB SPL; numbers below that indicate the degree of attenuation of outside sounds. The T 5 p’s provide a little more isolation from such sounds than do Audeze’s LCD-XCs, another audiophile-oriented, closed-back headphone model.
The impedance of the T 5 p’s is fairly flat, ranging from 32 to 45 ohms with a relatively flat phase curve.
The Beyerdynamics’ sensitivity, measured between 300Hz and 3kHz with a 1mW signal calculated for the specified 32 ohms impedance, is 103.4dB. That’s fantastic for large, audiophile-oriented headphones, and enough to ensure loud volume from almost any source device.
. . . Brent Butterworth
brentb@soundstagenetwork.com
I measured the Sonorous IIIs using a G.R.A.S. Model 43AG ear/cheek simulator, a Clio 10 FW audio analyzer, a laptop computer running TrueRTA software with an M-Audio MobilePre USB audio interface, a Musical Fidelity V-Can headphone amplifier, and an Audio-gd NFB-1AMP amplifier for distortion measurements. This is a “flat” measurement; no diffuse-field or free-field compensation curve was employed.
The Sonorous IIIs’ frequency response is flatter than I’m used to seeing from headphones of this type. Instead of the usual response peak around 3kHz, which is generally thought to make headphones sound more like speakers in an actual room, there’s a broad, shallow peak between 1.5 and 6kHz. I can’t recall seeing a measurement like this before, so I hesitate to speculate as to what effect it might have on the sound. I wonder if the lack of a 3kHz peak is why the Sonorous IIIs sounded a bit less spacious than some competing models.
Adding 70 ohms output impedance to the V-Can’s 5 ohms, to simulate the effects of using a typical low-quality headphone amplifier, has no significant effect on the Sonorous IIIs’ tonal balance.
This chart shows the Sonorous IIIs’ response compared with two well-regarded, midpriced closed-back models: the NAD Viso HP50s ($299) and the Oppo Digital PM-3s ($399). It’s easy to see that the Sonorous IIIs are something different, with less treble response than either competitor. But that’s not necessarily a bad thing -- the Sonorous IIIs’ somewhat rolled-off bass could counteract it, to give the headphones a perceived flat response.
Their spectral-decay (waterfall) plot indicates that the Sonorous IIIs seem to have a bit stronger initial resonance below 700Hz than I’m used to seeing, but it’s well damped, and drops to very low levels (-40dB and below) within 5 milliseconds.
The total harmonic distortion (THD) of the Sonorous IIIs is very low. Even at the extremely loud level of 100dBA, it rises to just 3% at 20Hz.
In this chart, the level of external noise is 75dB SPL; the numbers below that indicate the degree of attenuation of outside sounds. For reference, I’ve included another set of passive closed-back headphones, the NAD Viso HP50s, as well as that of a set of headphones with active noise canceling: the Bose QC25s ($299). The Sonorous IIIs’ isolation is not quite as good as the Viso HP50s’, probably because the Finals’ large earpads made it tough to get a good seal on the ear/cheek simulator (and on my actual, unsimulated ear and cheek). As always with this measurement, your results may vary; the better the fit, the better the isolation.
The Sonorous IIIs’ impedance is essentially flat, averaging 19 ohms, with negligible phase shift.
The sensitivity of the Sonorous IIIs, measured between 300Hz and 3kHz with a 1mW signal calculated for the specified impedance of 16 ohms, is 105.8dB. That’s excellent for headphones of this type; there should be no problem getting loud volumes from any source device.
. . . Brent Butterworth
brentb@soundstagenetwork.com
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