Foreword / YouTube Video Review
I was loaned these from the manufacturer for review. I was not paid nor did the manufacturer see my review before its release.
All my reviews are done on my own time with great care to give you all the best set of data and information I can provide in order to help you make a well-informed purchase decision. I offer this for free to all who are interested. In return, if you want to support this site please see the bottom of this review for ways you can help. It is greatly appreciated.
The review on this website is a brief overview and summary of the objective performance of this speaker. It is not intended to be a deep dive. Moreso, this is information for those who prefer “just the facts” and prefer to have the data without the filler. The video below has more discussion with respect to the technical merits and subjective notes I had during my listening sessions.
- Woofer: 4” treated paper cone, rubber surround, cast aluminum basket, vented pole
- Tweeter: 1” silk dome, dispersion-optimized waveguide, neodymium magnet
- Crossover: 12dB/Octave tweeter; 12dB/Octave woofer
- Enclosure Type: Rear-ported, dual flared taper port
- Frequency Response: 65Hz-20kHz
- Nominal Impedance: 8 Ohms
- Sensitivity: 85dB 1W/1M
- Power Handling: 15-80 Watts/Channel
- Dimensions (each): 8.9” (H) x 5.5” (W) x 8.2” (D)
- Weight (each): 6.14 lb.
As of this writeup MSRP is approximately $150/pair.
CTA-2034 (SPINORAMA) and Accompanying Data
All data collected using Klippel’s Near-Field Scanner. The Near-Field-Scanner 3D (NFS) offers a fully automated acoustic measurement of direct sound radiated from the source under test. The radiated sound is determined in any desired distance and angle in the 3D space outside the scanning surface. Directivity, sound power, SPL response and many more key figures are obtained for any kind of loudspeaker and audio system in near field applications (e.g. studio monitors, mobile devices) as well as far field applications (e.g. professional audio systems). Utilizing a minimum of measurement points, a comprehensive data set is generated containing the loudspeaker’s high resolution, free field sound radiation in the near and far field. For a detailed explanation of how the NFS works and the science behind it, please watch the below discussion with designer Christian Bellmann:
IMPORTANT SETUP INFO:
This speaker was measured with the reference point at the tweeter with the grille off. Speaker was broken in.
Measurements are provided in a format in accordance with the Standard Method of Measurement for In-Home Loudspeakers (ANSI/CTA-2034-A R-2020). For more information, please see this link.
CTA-2034 / SPINORAMA:
The On-axis Frequency Response (0°) is the universal starting point and in many situations it is a fair representation of the first sound to arrive at a listener’s ears.
The Listening Window is a spatial average of the nine amplitude responses in the ±10º vertical and ±30º horizontal angular range. This encompasses those listeners who sit within a typical home theater audience, as well as those who disregard the normal rules when listening alone.
The Early Reflections curve is an estimate of all single-bounce, first-reflections, in a typical listening room.
Sound Power represents all of the sounds arriving at the listening position after any number of reflections from any direction. It is the weighted rms average of all 70 measurements, with individual measurements weighted according to the portion of the spherical surface that they represent.
Sound Power Directivity Index (SPDI): In this standard the SPDI is defined as the difference between the listening window curve and the sound power curve.
Early Reflections Directivity Index (EPDI): is defined as the difference between the listening window curve and the early reflections curve. In small rooms, early reflections figure prominently in what is measured and heard in the room so this curve may provide insights into potential sound quality.
Early Reflections Breakout:
Floor bounce: average of 20º, 30º, 40º down
Ceiling bounce: average of 40º, 50º, 60º up
Front wall bounce: average of 0º, ± 10º, ± 20º, ± 30º horizontal
Side wall bounces: average of ± 40º, ± 50º, ± 60º, ± 70º, ± 80º horizontal
Rear wall bounces: average of 180º, ± 90º horizontal
Estimated In-Room Response:
In theory, with complete 360-degree anechoic data on a loudspeaker and sufficient acoustical and geometrical data on the listening room and its layout it would be possible to estimate with good precision what would be measured by an omnidirectional microphone located in the listening area of that room. By making some simplifying assumptions about the listening space, the data set described above permits a usefully accurate preview of how a given loudspeaker might perform in a typical domestic listening room. Obviously, there are no guarantees, because individual rooms can be acoustically aberrant. Sometimes rooms are excessively reflective (“live”) as happens in certain hot, humid climates, with certain styles of interior décor and in under-furnished rooms. Sometimes rooms are excessively “dead” as in other styles of décor and in some custom home theaters where acoustical treatment has been used excessively. This form of post processing is offered only as an estimate of what might happen in a domestic living space with carpet on the floor and a “normal” amount of seating, drapes and cabinetry.
For these limited circumstances it has been found that a usefully accurate Predicted In-Room (PIR) amplitude response, also known as a “room curve” is obtained by a weighted average consisting of 12 % listening window, 44 % early reflections and 44 % sound power. At very high frequencies errors can creep in because of excessive absorption, microphone directivity, and room geometry. These discrepancies are not considered to be of great importance.
Horizontal Contour Plot (normalized):
Vertical Contour Plot (normalized):
“Globe” Plots
Horizontal Polar (Globe) Plot:
This represents the sound field at 2 meters - above 200Hz - per the legend in the upper left.
Vertical Polar (Globe) Plot:
This represents the sound field at 2 meters - above 200Hz - per the legend in the upper left.
Additional Measurements
Impedance
Response Linearity
Step Response
Group Delay
Harmonic Distortion
Harmonic Distortion at 86dB @ 1m:
Harmonic Distortion at 96dB @ 1m:
Dynamic Range (Instantaneous Compression Test)
The below graphic indicates just how much SPL is lost (compression) or gained (enhancement; usually due to distortion) when the speaker is played at higher output volumes instantly via a 2.7 second logarithmic sine sweep referenced to 76dB at 1 meter. The signals are played consecutively without any additional stimulus applied. Then normalized against the 76dB result.
The tests are conducted in this fashion:
- 76dB at 1 meter (baseline; black)
- 86dB at 1 meter (red)
- 96dB at 1 meter (blue)
- 102dB at 1 meter (purple)
The purpose of this test is to illustrate how much (if at all) the output changes as a speaker’s components temperature increases (i.e., voice coils, crossover components) instantaneously.
Multitone Distortion
The following tests are conducted at (4) approximate equivalent output volumes: 70/79/87/96dB @ 1 meter. The (4) voltages listed in the legend result in these SPL values.
The test was conducted in (3) manners:
- Full bandwidth (20Hz to 20kHz)
- 80Hz to 20kHz
The reason for the two measurements is to simulate running the speaker full range vs using a high-pass filter at 80Hz. However, note: the 2nd test low frequency limit at 80Hz is a “brick wall” and doesn’t quite emulate a standard filter of 12 or 24dB/octave. But… it’s close enough.
For information on how to read the below data, watch this video:
- Full bandwidth (20Hz to 20kHz)
- 80Hz to 20kHz
Parting / Random Thoughts
See video linked above for subjective and objective analysis. I have provided a brief transcript below.
This is a $150 little compact bookshelf speaker sent to me by the company to review. I’m not sure if they’ll want it back yet. Just letting you know where they came from, though.
In the past I had reviewed the Neumi BS5 and BS5P and liked them. They’re cheap little speakers; not great sound quality but better than many others in their price category. This one is supposedly a step up with better parts, albeit smaller, using a 4” midwoofer rather than a 5” like its bigger brother.
So, on to my impressions:
I did my listening at a few feet away, trying to emulate how most would use these (aka: not as mains in a home theater). Overall my impression is positive. There is some notable resonance around 600Hz and again around 1kHz that I believe may be due to the port (the data seems to back this up).
Seems maybe there is some slight baffle step compensation mismatch but if you place the speaker near a wall then there is some boundary loading that helps this slightly. Natively, though, the midrange resonances were a bit annoying with certain tracks that happened to hit those notes and the high frequency is just a little too laid back in the nearfield. When you move back past a few feet, though, the HF balances out and sounds better, IMHO.
Bass is decent with an F3 of 83Hz and F10 at 55Hz. So, for its size the extension is reasonable.
Placed on a desk in the nearfield I would recommend either boosting the 400-500Hz region and bringing the tweeter level up above 4kHz. Or use a wide Q parametric filter at ~1.2kHz and drop the level down about 1.5dB to even up the response.
Output capability is actually a bit surprising for its size. Even at 96dB @ 1m the THD is below 3% until about 60Hz! But I’d still say you’ll want an 80Hz crossover to a subwoofer if you want lows. If you just want something to give you better sound than TV speakers or standard desktop speakers then these are a worthwhile option even without a subwoofer.
Overall, for $150 I think these are a pretty solid little speaker and if you have some EQ then you can make them quite good little performers.
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