Linearteam WinISD Pro
Transfer function magnitude
This graph shows gain in dB related to driver's limit efficiency n0. Which it theoretically
reaches at infinite frequency. This is the basic graph, which is needed most.
SPL
SPL graph shows Sound Pressure Level at specified distance at specified powerlevel, radiated
to half(2pi) space. To get the full-space value, subtract 6 dB from the reading. Because
driver's efficiency is related to ambient conditions, changing for example the project's
temperature, will change the calculated SPL level.
Transfer function phase
Phase shows the phase difference between the electrical input signal and acoustic output
signal. See the illustration below.
Group delay
Group delay describes how long spectrally infitesimally narrow sine burst signal takes to
travel through speaker's acoustic "filter". The flatter the group delay, the better. The
value itself is not a concern, other that if delay becomes too large, then it might be
difficult to match the design to other speaker's which might have less group delay. Large
groupdelay variations usually means large ringing when transient signals are applied to the
system. Mathematically it is the derivative of negative phase versus frequency in
radians/sec. So when phase changes linearly versus frequency, then the group delay has a
constant value. If you are wondering why the group delay of vented box is very different from
WinISD version 0.43 and below, the reason is that it calculated it wrong.
Cone Excursion
Cone excursion shows how much driver cone moves with sinusoidal excitation at chosen
powerlevel. The powerlevel is controlled in "plot"-tab. The power applied can be related to
excitation voltage with following relation: Eg=sqrt(P*Re), or P=Eg^2/Re where Eg is the RMS
voltage applied to driver's terminals, P is the input power in watts and Re is the DC
resistance of the voice coil. Please note that there is few different ways to express this
value. WinISD can be configured to show RMS, Peak, Peak-to-peak (p-p) values of the cone
excursion. RMS value is defined just as RMS value of any sine waveform. Peak value is the
difference between zero and the maximum value of sinusoidal waveform. Peak-to-peak is twice
the peak value, i.e. difference between minimum and maximum point of waveform. The peak value
is perhaps a most practical expression, because driver parameter Xmax indicates how much cone
can be deflected from it's rest position linearly, in either direction. If you want to
maximize power handling of any box, then adjust the box parameters so that cone excursion is
kept at minimum value possible. Of course the transfer function magnitude graph should be
taken into consideration also. In closed box, the minimum excursion is obtained, when
enclosure is as small as possible. Same basically applies to vented box, but there is a local
minimum at port tuning frequency. When comparing graphs between programs, please note that
many programs give the RMS excursion which is "wrong", in my opinion. I have seen some
programs, where the calculated excursion is RMS value, and limit is shown as peak. That gives
over-optimistic power handling impression. Please also note that this graph doesn't take
nonlinearities into consideration. But it let's you see when the nonlinearities are becoming
too great.
Air velocity - front/rear port
Air velocity graph shows how fast air mass travels in port. In order to keep chuffing noise
low, you should limit the peak velocity at 5% of velocity of sound, or about 17 m/s. Like the
cone excursion graph, the desired powerlevel is set also by same watts setting. Note that if
air velocity peaks exceeds previously mentioned level. This graph can also be configured to
show RMS, peak or peak-to-peak value. See the cone excursion graph explanation for RMS, peak
and peak-to-peak values.
Gain - front/rear port
This graph shows n0 (the driver reference efficiency) relative magnitude output of the front
or rear port. In conventional vented box, this graph shows relative sound pressure
contribution of the vent.
Maximum power
Maximum power indicates, what is the maximum powerhandling of the speaker at each frequency.
It shows either the Pe, which is maximum electrical input power based on thermal power
handling. Or if it is less, then it shows, how much power is needed to drive the cone to
maximum excursion Xmax. Again, you can obtain the required drive voltage by equation
Eg=sqrt(P*Re), where the Eg is RMS terminal input voltage of the driver, P is the input power
and Re is DC resistance of the driver voice coil.
Impedance/impedance phase
Impedance graph shows, what kind of impedance load the amplifier will see. The impedance
shown is the impedance of each driver, if there is many of them or there is an isobarik
configuration. In LspCAD terms, drivers have "Separate Sources". The lower the reading, then
higher the load on the amplifier. Impedance graphs shows actually the modulus of the complex
impedance and phase angle (impedance phase) graph shows whether the load is resistive (phase
about 0 degrees), inductive (phase positive) or capacitive (phase negative). Reactive load
doesn't actually dissipate any power, but instead of dissipating it, it returns it to driving
amplifier. In classic linear amplifier, this power is wasted. D-class amplifiers utilize this
and return this energy to the power supply. High capacitive load is difficult for any
feedbacked amplifier, because it eats the phase margin of the amplifier and may cause it to
begin oscillating. This impedance gives only steady-state impedance for sinusoidal signal.
For more complex input signal, the current drawn from the amplifier may be greater than
calculated with this graph, because of energy storage of the impedance, although this may be
very rare with normal audio signals. There is an AES paper about this written by Matti Otala
and Pertti Huttunen.