Linear parameters. Mechanical Parameters (using laser)

Similar documents
Balanced Armature Check (BAC)

Fast and Accurate Measurement of Linear Transducer Parameters

Causes for Amplitude Compression AN 12

Classic 1 Tweeter. Type Number: D2904/ Features:

Linear Lumped Parameter Measurement

Large Signal Performance of Tweeters, Micro Speakers and Horn Drivers

Reduce distortion by shifting Voice Coil AN 21

The study on the woofer speaker characteristics due to design parameters

Dynamic Generation of DC Displacement AN 13

Maximizing LPM Accuracy AN 25

Application Note L26ROY

d anish sound technology

CX15N351 COAXIAL DATASHEET

BETA-8A American Standard Series

LAB12 Professional Series

A Guide to Reading Transducer Specification Sheets

danish sound technology

The Woofer Tester 2. Precision Thiele-Small & RLC Measurement Simulation and Box Analysis. Web: Phone:

Tolerances of the Resonance Frequency f s AN 42

BETA-10A American Standard Series

BETA-8A American Standard Series

Assessing Large Signal Performance of Transducers

DEFINIMAX 4015LF Professional Series

The Woofer Tester Pro. Integrated Speaker Measurement & Design. Web: Phone:

DELTA-12LFA American Standard Series

Road Map of the Workshop

The CVEN speakers were designed by the Vibe Research and Development team of UK and European engineers headed by company founder Carl Venables.

KAPPA-15A American Standard Series

BETA-12LTA American Standard Series

DELTALITE -II 2515 Neodymium

DELTA-15LFA American Standard Series

3D Distortion Measurement (DIS)

Measurement of Amplitude Modulation AN 6

DELTALITE -II 2512 Neodymium

KILOMAX PRO 15A Professional Series

American Standard Series

File: Delta10ALargeVentedBox125Watts.bb6

DELTA PRO-8B Professional Series

BETA-12A-2 American Standard Series

File: Delta12ALargerVentedBox50Watts.bb6

Big Sound from Small Speakers Part 1. Wolfgang Klippel

C7: Speaker Components

FINEBox T U T O R I A L

Hot and Nonlinear Loudspeakers at High Amplitudes

Since the rest position is the optimal average working point, DC offset leads to several undesirable consequences: reduced excursion capabilities,

File: DeltaPro15LargeVentedBox200Watts.bb6

File: DeltaPro12SmallMidHighBox400Watts.bb6

ECW100 / ECW120 ENCORE SERIES SUBWOOFERS

File: Delta15ASmallVentedBox125Watts.bb6

FINEBox. Non-Linear High Power Box Design Program For Hi-Fi, PA and Micro loudspeakers T U T O R I A L

Measurement at defined terminal voltage AN 41

BLACK WIDOW SUPER STRUCTURE

Electrical and Mechanical Measurements of Loudspeakers and Sound System Equipment. Tutorial to a new IEC Standard Project by Wolfgang Klippel,

Measurement of weighted harmonic distortion HI-2

Audio System Evaluation with Music Signals

B&C Speaker SpA Bagno a Ripoli (FI), Italia

Product Specification of BURY Speaker

DELTA-15LF-4. American Standard series. SPL vs Freq. Specification. Materials of Construction

Sheffield Pro Series. Sheffield Pro Sheffield Pro

DELTA PRO Professional series. SPL vs Freq. Specification. Materials of Construction

C5A Series. 8" Dual Cone Loudspeaker Available With Transformer. Specifications. Features. Thiele-Small Parameters. Applications. General Description

Measurement of Weighted Harmonic Distortion HI-2

Fs Hz Qts Vas Ltrs. Xmax mm P. db 2.83V/m.

Active Compensation of Transducer Nonlinearities. W. Klippel KLIPPEL GmbH, Dresden, Germany

3D Intermodulation Distortion Measurement AN 8

Master class. Germanium GL- C6.2 Loudspeaker Art from Rainbow. BEST PRODUCT High- end CAR & HIFI 2/2014

Loudspeaker Data Reliable, Comprehensive, Interpretable

Distortion and Power Compression in Low-frequency Transducers

Mobile Fidelity_Specifications

Driver Properties --Description-- Name: Delta-10 (8 ohm) Type: Standard one-way driver Company: Eminence Speaker LLC Comment: Revised NOV 2005

THE UNDER HUNG VOICE COIL MOTOR ASSEMBLY REVISITED IN THE LARGE SIGNAL DOMAIN BY STEVE MOWRY

Normalized Amplitude Response (db-spl/hz) Custom Amplitude Response (db-spl/hz at 1 m) with 300 watts. Maximum Acoustic Power (db-spl/hz at 1 m)

Measurement of Equivalent Input Distortion. Wolfgang Klippel. Klippel GmbH,Dresden, 01277, Germany, Fellow

Find your local distributor at

(i) Determine the admittance parameters of the network of Fig 1 (f) and draw its - equivalent circuit.

LST - Linear Suspension Test

Optimal Voice Coil Rest Position AN 1

An Enclosure Design for TEBM35C10-4 BMR Loudspeaker Driver

Error Correction of Loudspeakers: A study of Loudspeaker Design supported by Digital Signal Processing

Micro Receiver Analysis

High Current Amplifier

A R T A - A P P L I C A T I O N N O T E

Normalized Amplitude Response (db-spl/hz) Custom Amplitude Response (db-spl/hz at 1 m) with 125 watts. Maximum Acoustic Power (db-spl/hz at 1 m)

Architect s and Engineer s Specifications. 409 SERIES DUPLEX LOUDSPEAKERS The loudspeaker shall be a Duplex type

Dual Diaphragm Asymmetric Compression Drivers

SPECIFICATIONS QW -1. Listen To This. Mid Frequency Section: 101 db SPL, (2 Volt input) High Frequency Section: 111 db SPL, (2.

APPLICATION NOTE PROFESSIONAL LOUDSPEAKERS SINGLE 21, BAND-PASS SUBWOOFER KIT

C803A Series. 8 " Coaxial Loudspeaker Available With Transformer. Specifications. Features. Thiele-Small Parameters. Applications. General Description

INTRODUCTION. the DALI EPICON 6

Rub & Buzz Detection with Golden Unit AN 23

Transfer Function (TRF)

Motor Nonlinearities in Electrodynamic Loudspeakers: Modelling and Measurement

pro audio hf devices components guitar bass

Alternating Current. Slide 1 / 69. Slide 2 / 69. Slide 3 / 69. Topics to be covered. Sources of Alternating EMF. Sources of alternating EMF

Alternating Current. Slide 2 / 69. Slide 1 / 69. Slide 3 / 69. Slide 4 / 69. Slide 6 / 69. Slide 5 / 69. Topics to be covered

ENSEA conference Loudspeaker driver Loudspeaker enclosure. Jeremie Huscenot January 8, 2000

Subwoofers UNDSTREAM. i. - I. \ INSTALLATION GUIDE. T E C H Iv 0 L,O G I E S

AP Physics C. Alternating Current. Chapter Problems. Sources of Alternating EMF

Chapter 30 Inductance, Electromagnetic. Copyright 2009 Pearson Education, Inc.

Modelling the Electrical Parameters Of A Loudspeaker Motor System With The AC-DC Module

Transcription:

Linear parameters Name Value Unit Comment Electrical Parameters Re 3.68 Ohm electrical voice coil resistance at DC Le 0.834 mh frequency independent part of voice coil inductance L2 1.560 mh para-inductance of voice coil R2 5.12 Ohm electrical resistance due to eddy current losses Cmes 405.84 µf electrical capacitance representing moving mass Lces 69.59 mh electrical inductance representing driver compliance Res 36.53 Ohm resistance due to mechanical losses fs 29.9 Hz driver resonance frequency Mechanical Parameters (using laser) Mms 127.220 g mechanical mass of driver diaphragm assembly including air load and voice coil mechanical mass of voice coil and diaphragm without air Mmd (Sd) 123.573 g load Rms 8.582 kg/s mechanical resistance of total-driver losses Cms 0.222 mm/n mechanical compliance of driver suspension Kms 4.50 N/mm mechanical stiffness of driver suspension Bl 17.71 N/A force factor (Bl product)

Lambda s 0.011 suspension creep factor Loss factors Qtp 0.256 total Q-factor considering all losses Qms 2.789 mechanical Q-factor of driver in free air considering Rms only Qes 0.281 electrical Q-factor of driver in free air considering Re only Qts 0.255 total Q-factor considering Re and Rms only Vas 37.6878 l equivalent air volume of suspension n0 0.347 % reference efficiency (2 pi-radiation using Re) Lm 87.60 db characteristic sound pressure level (SPL at 1m for 1W @ Re) Lnom 87.97 db nominal sensitivity (SPL at 1m for 1W @ Zn) rmse Z 5.61 % root-mean-square fitting error of driver impedance Z(f) rmse Hx 4.05 % root-mean-square fitting error of transfer function Hx (f) Series resistor 0.00 Ohm resistance of series resistor Sd 346.36 cm diaphragm area Electrical Impedance The two figures below show the magnitude and the phase response of the measured and estimated transfer function Z(f)= U(f)/I(f) where U is the terminal voltage and I is the current. The solid curve is the ratio of the measured spectra U(f), I(f) while the thin curve is the impedance of the linear driver equivalent circuit using the linear model and the identified electrical parameters shown

Displacement Transfer Function The figure below shows the magnitude of the measured and estimated transfer function Hx(f)= X(f)/U(f) between the voice coil displacement X and the terminal voltage U. The solid black curve is the ratio of the measured spectra X(f), U(f) while the thin black curve is the transfer function based on the linear driver equivalent circuit using the identified electrical and mechanical parameters as well as the creep parameter. The dashed red curve is based on the conventional model without considering the creep factor.

This report is generated by the report generator in the frame software db-lab in the Klippel Analyzer System. Using an existing report as template, the old data are replaced by the results of the current measurement automatically. Date: 01/19/07 Time: 14:51:15 Username: Administrator (c)08/2000 Klippel GmbH Germany - http://www.klippel.de/ KLIPPEL ANALYZER SYSTEM Detailed Report Large Signal Identification (LSI) Driver Name: Driver Comment: Measurement: LSI Woofer+Box Measurement Comment: Nonlinear Parameters

Power Series Expansion Symbol Number Unit Comment Displacement Limits X Bl @ Bl min=82% X C @ C min=75% X L @ Z max=10 % 5.9 mm 4.6 mm 4.7 mm X d @ d2=10% 38.4 mm thresholds can be changed in Processing property page Displacement limit due to force factor variation Displacement limit due to compliance variation Displacement limit due to inductance variation Displacement limit due to IM distortion (Doppler) alpha Heating of voice coil by eddy currents

alphaorg Heating of voice coil by eddy currents (without limits) Rtv K/W thermal resistance coil ==> pole tips rv Ws/Km air convection cooling depending on velocity Rtm K/W thermal resistance magnet ==> environment tau m min thermal time constamt of magnet Ctm Ws/K thermal capacity of the magnet tau v s thermal time constant of voice coil Ctv Ws/K thermal capacity of the voice coil delta Tw K Temperature increase in Warm Resistance Mode delta Tc K Temperature increase in Convection Mode delta Te K Temperature increase in Eddy Mode Pcoil(warm) W Pcoil in warm mode Pcoil(conv) W Pcoil in convection mode Ptv(mag.beg) Ptv(mag.mid) Ptv(mag.end) Ptm(mag.beg) Ptm(mag.mid) Ptm(mag.end) W W W W W W power heating the coil at beginning of magnet mode power heating the coil sampled in the middle of magnet mode power heating the coil at end of magnet mode power heating the magnet at beginning of magnet mode power heating the magnet sampled in the middle of magnet mode power heating the magnet at end of magnet mode f1-0.004068 1/A f2-0.000262 1/A^2 coefficient (1) of Inductance over current (flux modulation) coefficient (2) of Inductance over current (flux modulation) Bl0 = Bl (X=0) 18.113 N/A constant part in force factor Bl1 0.13201 N/Amm Bl2-0.051071 N/Amm^2 Bl3 0.0013792 N/Amm^3 Bl4-0.00059795 N/Amm^4 1st order coefficient in force factor 2nd order coefficient in force factor 3rd order coefficient in force factor 4th order coefficient in force factor

Bl5 Bl6 Bl7 Bl8 N/Amm^5 N/Amm^6 N/Amm^7 N/Amm^8 5th order coefficient in force factor 6th order coefficient in force factor 7th order coefficient in force factor 8th order coefficient in force factor L0 = Le (X=0) 1.0151 mh constant part in inductance L1-0.0035913 mh/mm 1st order coefficient in inductance L2-0.0078351 mh/mm^2 L3 L4 L5 L6 L7 L8 2nd order coefficient in inductance 3rd order coefficient in inductance 3.4595e-005 mh/mm^3 3.3433e-005 mh/mm^4 4th order coefficient in inductance mh/mm^5 5th order coefficient in inductance mh/mm^6 6th order coefficient in inductance mh/mm^7 7th order coefficient in inductance mh/mm^8 8th order coefficient in inductance C0 = Cms (X=0) 0.35584 mm/n constant part in compliance C1 0.0092292 1/N C2-0.0025585 1/Nmm C3 C4 C5 C6 C7 C8-6.2611e- 005 1/Nmm^2 8.6336e-006 1/Nmm^3 1/Nmm^4 1/Nmm^5 1/Nmm^6 1/Nmm^7 1st order coefficient in compliance 2nd order coefficient in compliance 3rd order coefficient in compliance 4th order coefficient in compliance 5th order coefficient in compliance 6th order coefficient in compliance 7th order coefficient in compliance 8th order coefficient in compliance K0 = Kms (X=0) N/mm constant part in stiffness K1-0.082247 N/mm^2 1st order coefficient in stiffness K2 0.024675 N/mm^3 2nd order coefficient in stiffness K3 - N/mm^4 3rd order coefficient in stiffness

0.00026711 K4 3.0833e-005 N/mm^5 4th order coefficient in stiffness Xpse 9.6 mm -Xpse < X < Xpse, range where power series is fitted Derived Loudspeaker Parameters

Linear Parameters Symbol Note: Delta Tv = Tv-Ta Large + Warm Large + Cold Small Signal 42 0 0 K Unit Xprot 9.6 9.6 3.6 mm Comment for accurate small signal parameters, use LPM module increase of voice coil temperature during the measurement maximal voice coil excursion (limited by protection system) Re (Tv) 4.27 3.68 3.68 Ohm (imported) voice coil resistance considering increase of voice coil temperature Tv Le (X=0) 1.02 1.02 0.93 mh voice coil inductance at the rest

L2 (X=0) 1.88 1.88 1.65 mh R2 (X=0) 4.38 4.38 4.05 Ohm Cmes (X=0) Lces (X=0) 501 501 459 µf 90.77 90.77 75.57 mh Res (X=0) 23.48 23.48 17.91 Ohm position of the voice coil para-inductance at the rest position due to the effect of eddy current resistance at the rest position due to eddy currents electrical capacitance representing moving mass electrical inductance at the rest position representing driver compliance resistance at the rest position due to mechanical losses Qms (X=0, Tv) 1.74 1.74 1.40 Qes (Tv) 0.26 0.22 0.25 Qts (X=0, Tv) 0.22 0.20 0.21 mechanical Q-factor considering Rms only electrical Q-factor considering Re (Tv) only total Q-factor considering Re (Tv) and Rms only fs 23.6 23.6 27.0 Hz driver resonance frequency Mms 127.220 127.220 127.220 g Rms (X=0) Cms (X=0) 10.826 10.826 15.466 kg/s 0.36 0.36 0.27 mm/n Bl (X=0) 17.71 17.71 17.71 N/A Vas 60.4090 60.4090 46.1579 l (imported) mechanical mass of driver diaphragm assembly including voice-coil and air load mechanical resistance of total-driver losses mechanical compliance of driver suspension at the rest position (imported) force factor at the rest position (Bl product) equivalent air volume of suspension N0 0.297 0.344 0.344 % reference efficiency (2Pi-sr radiation using Re) Lm 86.9 87.5 87.5 db characteristic sound pressure level Sd 346.36 346.36 346.36 cm diaphragm area Temporal Variations of the Stiffness K MS (t, x=0)

Temporal Variations of the Voice Coil Resistance R E (t)

Transducer State Symbol Value Unit Comment Date 2007-01-19 Time 14:34:41 Serial number 332 Mode Nonlinear Mode 5(7) Record 524/524 Laser signal reliable t 00:14:31 h:min:s measurement time Time remaining 00:00:29 h:min:s recalculated at thermal mode(a) Ei (t) 8.2 % error current measurement Ex (t) 1.8 % error laser measurement Eu (t) 14.5 % error amplifier check Delta Tv (Delta Tlim) 42.0 (60.0) K increase of voice coil temperature (limit) Blmin (Bllim) 40.0 (40.0) % minimal force factor ratio (limit) Cmin (Clim) 44.7 (40.0) % minimal compliance ratio (limit) P (Plim) 48.8832 (80.00) W real electrical input power (limit) Lmin 55.7 % minimal inductance ratio

Pn 92.203179 W nominal electrical input power P Re 36.748031 W Power heating voice coil Irms 2.934 A rms value of the electrical input current Urms 19.204 V rms value of the electrical voltage at the transducer terminals Ipeak 9.979 A peak value of the electrical input current Upeak 68.937 V peak value of the electrical voltage at the transducer terminals PC 1.29 db thermal power compression factor Glarge (Gmax) 9.7 (26.0) db gain of the excitation amplitude increased in the large signal domain (maximum) Mech. system abs. import used to identify mechanical system in absolute quantities Xdc 0.2 mm Xpeak 8.6 mm Xbottom -7.2 mm Xp+ 7.8 mm Xp- -7.2 mm dc component of voice coil excursion measured in the last update intervall positive peak value of voice coil excursion measured in the last update intervall negative peak value (bottom) of voice coil excursion measured in the last update intervall upper limit of displacement range (99% probability) lower limit of displacement range (99% probability) Xprot 9.6 mm maximal voice coil excursion allowed by protection system v rms 0.5 m/s voice coil velocity Db 20.1 % Dl 17.6 % Dc 6.1 % distortion factors representing contribution of nonlinear force factor distortion factor representing contribution of nonlinear inductance distortion factor representing contribution of nonlinear compliance R th total 1.14 K/W Delta Tv / P Re Voltage Probability Density Function pdf(u)

Voltage u peak (t) and Current i peak (t) Voice Coil Temperature Δ T V (t) and Power P(t)

Displacement x(t) Displacement Probability Density Function pdf(x)

Distortion Analysis Remedies for Transducer Nonlinearities

Report generated: Date: 01/19/07 Time: 14:51:55 Username: Administrator (c)08/2000 Klippel GmbH Germany - http://www.klippel.de/

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback