Weiss JASON Owner's Manual

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Weiss JASON Owner's Manual | Manualzz

Weiss Engineering Ltd.

Florastrasse 42, 8610 Uster, Switzerland www.weiss-highend.com

JASON

OWNERS MANUAL

OWNERS MANUAL FOR WEISS JASON CD TRANSPORT

INTRODUCTION

D ear

C ustomer

Congratulations on your purchase of the JASON CD Transport and welcome to the family of Weiss equipment owners!

The JASON is the result of an intensive research and development process. Research was conducted both in analog and digital circuit design, as well as in signal processing algorithm specification.

On the following pages I will introduce you to our views on high quality audio processing. These include fundamental digital and analog audio concepts and the JASON CD Transport.

I wish you a long-lasting relationship with your JASON.

Yours sincerely,

Daniel Weiss

President, Weiss Engineering Ltd.

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TABLE OF CONTENTS

4

5

6

A short history of Weiss Engineering

Our mission and product philosophy

Advanced digital and analog audio concepts explained

6 Jitter Suppression, Clocking

8 Upsampling, Oversampling and Sampling Rate Conversion in General

11 Reconstruction Filters

12 Analog Output Stages

12 Dithering

14 The JASON CD Transport

14 Features

17 Operation

21 Technical Data

22 Contact

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A SHORT HISTORY OF WEISS ENGINEERING

After studying electrical engineering, Daniel Weiss joined the Willi Studer (Studer - Revox) company in Switzerland. His work included the design of a sampling frequency converter and of digital signal processing electronics for digital audio recorders.

In 1985, Mr. Weiss founded the company Weiss Engineering Ltd. From the outset the company concentrated on the design and manufacture of digital audio equipment for mastering studios. Its first product was the modular "102 Series" system. After 23 years, this system is still up to date

(24 bit / 96kHz) and is still being sold. Hundreds of Mastering Studios around the world use it every day.

In the early nineties the „Gambit Series“ was launched, taking ergonomics and sonic quality to new heights. The „Gambit Series“consists of stand-alone units like Equalizer, Denoiser / Declicker,

Dynamics Processor, A/D converter, D/A converter, Sampling Frequency Converter, Dithering etc.

40 bit floating point processors and sampling rates up to 96kHz are employed.

In 2001 we have decided to enter the High-End Hi-Fi market which offers a comparable clientele to that of the Mastering Studios. Both consist of critical and discerning listeners, who are in constant search for the best audio reproduction equipment or the best audio tools respectively.

Our list of clients includes big names, like SONY, BMG, EMI, Warner, Hit Factory, Abbey Road,

Teldec, Telarc, Unitel, Gateway Mastering (Bob Ludwig), Bernie Grundman Mastering, Masterdisk,

Sterling Sound, Whitfield Street, Metropolis and hundreds more.

For a more comprehensive list you are invited to visit our pro audio website at www.weiss.ch

.

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OUR MISSION AND PRODUCT PHILOSOPHY

The wealth of experience we have gained in over 20 years of designing products for top Mastering

Engineers, we now apply to the design of outstanding High-End Hi-Fi products.

Our mission is to create equipment which becomes classic right from the outset; - outstanding in sonics and design.

These are some of the milestones at Weiss Engineering:

1985 Introduction of the "102 Series", a 24 bit modular digital audio processor for Mastering

Studios

1986 Introduction of one of the first sample rate converters for digital audio

1987 Introduction of one of the first digital equalizers

1989 Introduction of one of the first digital dynamics processors

1991 Introduction of the "Ibis" digital mixing console, built for the mix-down of classical music

1993 Introduction of the "Gambit" Series of digital audio processors, which employ 40 bit floating point processing and sport an extremely ergonomic user interface

1995 First 96kHz sampling rate capable products delivered

2001 Introduction of the MEDEA, our High-End Hi-Fi D/A converter and the first product in our

High-End Series

2004 Introduction of the JASON CD Transport

2007 Introduction of the CASTOR, our High-End Hi-Fi Power Amplifier

2008 Introduction of the MINERVA Firewire DAC and the VESTA Firewire – AES/EBU Interface

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ADVANCED DIGITAL AND ANALOG AUDIO CONCEPTS EXPLAINED

Jitter Suppression and Clocking

What is jitter and how does it affect audio quality? In the audio field the term jitter designates a timing uncertainty of digital clock signals. E.g. in an Analog to Digital Converter (A/D) the analog signal is sampled (measured) at regular time intervals; in the case of a CD, 44100 times a second or every 22.675737.. microseconds.

If these time intervals are not strictly constant then one talks of a jittery conversion clock. In practice it is of course not possible to generate exactly the same time interval between each and every sample. After all, even digital signals are analog in their properties and thus are influenced by noise, crosstalk, power supply fluctuations, temperature etc.

Hence a jittery clock introduces errors to the measurements taken by the A/D, resulting from measurements being taken at the wrong time. One can easily observe that the level of the error introduced is higher during high audio frequencies, because high frequency signals have a steeper signal form.

A good designer takes care that the jitter amount in his/her design is minimized as well as possible.

What type of equipment can be compromised by jitter?

There are three types: The A/D Converter as described above, then there is the D/A Converter where the same mechanism as in the A/D Converter applies and the third is the Asynchronous

Sample Rate Converter (ASRC). The ASRC is not something usually found in Hi-Fi systems. It is used by Sound Engineers to change the sample rate from e.g. 96kHz to 44.1kHz, or e.g. for putting a 96kHz recording onto a 44.1kHz CD.

You may now argue that in High-End Hi-Fi there are such things as „Oversamplers“ or

„Upsamplers“.

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Yes, those are in essence sampling rate converters, however in a well designed system these converters employ a synchronous design, where jitter does not play any role. Of course a conversion between 96kHz and 44.1kHz as in the example above, can be done in a synchronous manner as well. An ASRC in fact is only required either where one or both of the sampling frequencies involved are changing over time („varispeed“ mode of digital audio recorders) or where it is unpractical to synchronize the two sampling frequencies.

So basically in Hi-Fi jitter matters where there are A/D or D/A converters involved. CD and DVD players are by far the most numerous type of equipment employing D/A converters. And of course stand-alone D/A converters. Jitter, being an analog quantity, can creep in at various places. The

D/A converter built into CD or DVD players can be „infected“ by jitter through various crosstalk mechanisms, like power supply contamination by power hungry motors (spindle / servo) or microphony of the crystal generating the sampling clock or capacitive / inductive crosstalk between clock signals etc.

In the standalone D/A converter jitter can be introduced by inferior cables between the source

(e.g. CD player) and the D/A converter unit or by the same mechanisms as described above except for the motors of course.

In the case of a stand-alone D/A converter (as the MEDEA), one has to take two different jitter contamination pathes into account.

One is the internal path where internal signals can affect the jitter amount of the sampling clock generator. Here, all the good old analog design principles have to be applied. Such as shielding from electric or magnetic fields, good grounding, good power supply decoupling, good signal transmission between the clock generator and the actual D/A chip.

The other path is the external signal coming from the source to which the sampling clock has to be locked. I.e. the D/A converter has to run synchronous to the incoming digital audio signal and thus the frequency of the internal sampling clock generator has to be controlled so that it runs at the same sampling speed as the source (CD transport). This controlling is done by a Phase Locked

Loop (PLL) which is a control system with error feedback. Of course the PLL has to be able to follow the long term fluctuations of the source, e.g. the sampling rate of the source will alter slightly over time or over temperature, it will not be a constant 44.1kHz in the case of a CD. But the PLL should not follow the short term fluctuations (jitter). Think of the PLL as beeing like a very slow-reacting fly-wheel.

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In the MEDEA we employ a two stage PLL circuitry which very effectively suppresses jitter. A common problem with most PLLs used in audio circuitry is that they suppress jitter only for higher frequencies. Jitter frequencies which are low (e.g. below 1kHz or so) are often only marginally suppressed. It has been shown that low frequency jitter can have a large influence on the audio quality though. The MEDEA suppresses even very low frequency jitter components down to the sub-Hertz range.

This means that the MEDEA is virtually immune to the quality of the audio source regarding jitter.

For a CD player as a source this means that as long as the data is read off the CD in a correct manner (i.e. no interpolations or mutes) you should hardly hear any difference between different makes of CD players or between different pressings of the same CD. Also „accessories“ like disk dampening devices or extremely expensive digital cables will not make any difference in sonic quality. Of course it is always a good idea to have a good quality cable for digital (or analog) audio transmission - but within reason.

Upsampling, Oversampling and Sampling Rate Conversion in

General

In consumer audio circles the two terms oversampling and upsampling are in common use. Both terms essentially mean the same, a change in the sampling frequency to higher values.

Upsampling usually means the change in sampling rate using a dedicated algorithm (e.g. implemented on a Digital Signal Processor chip (DSP)) ahead of the final D/A conversion (the D/A chip), while oversampling means the change in sampling rate employed in today’s modern D/A converter chips themselves.

But let’s start at the beginning. What is the sampling frequency? For any digital storage or transmission it is necessary to have time discrete samples of the signal which has to be processed.

I.e. the analog signal has to be sampled at discrete time intervals and later converted to digital numbers. (Also see "Jitter Suppression and Clocking" above)). This sampling and conversion process happens in the so called Analog to Digital Converter (A/D). The inverse in the Digital to

Analog Converter (D/A).

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A physical law states that in order to represent any given analog signal in the digital domain, one has to sample that signal with at least twice the frequency of the highest frequency contained in the analog signal. If this law is violated so called aliasing components are generated which are perceived as a very nasty kind of distortion. So if one defines the audio band of interest to lie between 0 and 20 kHz, then the minimum sampling frequency for such signals must be 40kHz.

For practical reasons explained below, the sampling frequency of 44.1kHz was chosen for the CD.

A sampling frequency of 44.1kHz allows to represent signals up to 22.05kHz. The designer of the system has to take care that any frequencies above 22.05kHz are sufficiently suppressed before sampling at 44.1kHz. This suppression is done with the help of a low pass filter which cuts off the frequencies above 22.05kHz. In practice such a filter has a limited steepness, i.e. if it suppresses frequencies above 22.05kHz it also suppresses frequencies between 20kHz and 22.05kHz to some extent. So in order to have a filter which sufficiently suppresses frequencies above 22.05kHz one has to allow it to have a so called transition band between 20kHz and 22.05kHz where it gradually builds up its suppression.

Note that so far we have talked about the so called anti-aliasing filter which filters the audio signal ahead of the A/D conversion process. For the D/A conversion, which is of more interest to the

High-End Hi-Fi enthusiast, essentially the same filter is required. This is because after the D/A conversion we have a time discrete analog signal, i.e. a signal which looks like steps, having the rate of the sampling frequency.

Such a signal contains not only the original audio signal between 0 and 20kHz but also replicas of the same signal symmetrical around multiples of the sampling frequency. This may sound complicated, but the essence is that there are now signals above 22.05kHz. These signals come from the sampling process. There are now frequencies above 22.05kHz which have to be suppressed, so that they do not cause any intermodulation distortion in the amplifier and speakers, do not burn tweeters or do not make the dog go mad.

Again, a low pass filter, which is called a „reconstruction filter“, is here to suppress those frequencies. The same applies to the reconstruction filter as to the anti-aliasing filter: Pass-band up to 20kHz, transisition-band between 20kHz and 22.05kHz, stop-band above 22.05kHz. You may think that such a filter is rather "steep", e.g. frequencies between 0 and 20kHz go through unaffected and frequencies above 22.05kHz are suppressed to maybe 1/100'000th of their initial value. You are right, such a filter is very steep and as such has some nasty side effects.

For instance it does strange things to the phase near the cutoff frequency (20kHz) or it shows

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OWNERS MANUAL FOR WEISS JASON CD TRANSPORT ringing due to the high steepness. In the early days of digital audio these side effects have been recognized as beeing one of the main culprits for digital audio to sound bad.

So engineers looked for ways to enhance those filters. They can’t be eliminated because we are talking laws of physics here. But what if we run the whole thing at higher sampling rates? Like

96kHz or so? With 96kHz we can allow frequencies up to 48kHz, so the reconstruction filter can have a transition band between 20kHz and 48kHz, a very much relaxed frequency response indeed. So let’s run the whole at 96kHz or even higher! Well – the CD stays at 44.1kHz. So in order to have that analog lowpass filter (the reconstruction filter) to run at a relaxed frequency response we have to change the sampling frequency before the D/A process. Here is where the

Upsampler comes in. It takes the 44.1kHz from the CD and upsamples it to 88.2kHz or 176.4kHz or even higher. The output of the upsampler is then fed to the D/A converters which in turn feeds the reconstruction filter.

All modern audio D/A converter chips have such an upsampler (or oversampler) already built into the chip. One particular chip, for instance, upsamples the signal by a factor of eight, i.e. 44.1kHz ends up at 352.8kHz. Such a high sampling frequency relaxes the job of the reconstruction filter very much, it can be built with a simple 3 rd

order filter.

So, how come that upsamplers are such a big thing in High-End Hi-Fi circles? The problem with the upsamplers is that they are filters again, digital ones, but still filters. So in essence the problem of the analog reconstruction filter has been transferred to the digital domain into the upsampler filters. The big advantage when doing it in the digital domain is that it can be done with a linear phase response, which means that there are no strange phase shifts near 20kHz and the ringing can also be controlled to some extent. Digital filters in turn have other problems and of course have quite a few degrees of freedom for the designer to specifiy. This means that the quality of digital filters can vary at least as much as the quality of analog filters can. So for a High-End Hi-Fi designer it is a question whether the oversampling filter built into the D/A chips lives up to his/her expectations. If not, he/she can chose to design his/her own upsampler and bypass part of or the whole oversampler in the D/A chip. This gives the High-End Hi-Fi designer yet another degree of freedom to optimize the sonic quality of the product.

For the MEDEA we have decided to do part of the upsampling (the most critical part in fact) in the

Digital Signal Processor (DSP) chip external to the D/A chip.

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Reconstruction Filters

Reconstruction filters have been mentioned in the "Upsampling, Oversampling and Sampling Rate

Conversion in General" paragraph above. If you have read that paragraph you know what the purpose of the reconstruction filter is. The main point about this analog filter is that its frequency response should be as smooth and flat as possible in order to have a virtually linear phase response. The MEDEA employs a 3 rd

order filter for that purpose. 3 rd

order is sufficient to suppress the frequencies above approximately 176.4kHz. 176.4kHz because the D/A converter in the

MEDEA is running at 352.8kHz (or 384kHz) sampling frequency.

Analog Output Stages

The MEDEA employs class A output stages with a virtually zero ohm output impedance. Class A inherently guarantees very low distortion figures even when operating the amplifier in open loop, i.e. without feedback. The feedback is added to lower the distortion figures even further. The distortion figures of the MEDEA, which by the way are excellent, are predominantely caused by the

D/A converter and not by the output stage.

A very low output impedance assures that the performance of the MEDEA and the subsequent amplifier combination is not compromised by the cables between the two or by the input impedance characteristics of the amplifier. A low output impedance can be difficult when it comes to stability issues, but we have taken care of that problem in the MEDEA.

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Dithering

You have probably not heard the term dithering in conjunction with audio. Actually it is a term widely used in the professional audio realm but not so much in the High-End Hi-Fi market.

What is dithering? Suppose a digital recording has been made with a 24 bit A/D converter and a 24 bit recorder. Now this recording should be transferred to a CD which has just 16 bits per sample, as you know. What to do with those 8 bits which are too many? The simplest way is to cut them off, truncate them. This, unfortunately, generates harmonic distortions at low levels, but which nonethless cause the audio to sound harsh and unpleasant. The harmonic distortion is generated because the eight bits which are cut off from the 24 bits are correlated with the audio signal, hence the resulting error is also correlated and thus there are distortions and not just noise (noise would be uncorrelated). The dithering technique now is used to de-correlate the error from the signal.

This can be achieved by adding a very low level noise to the original 24 bit signal before truncation. After truncation the signal does not show any distortion components but a slightly increased noise floor. This works like magic..... the distortion is replaced by a small noise – much more pleasant.

I have given the example of a 24 bit recording which has to be truncated to 16 bits. Where is the application in High-End Hi-Fi audio? More and more signal processing is implemented in the digital domain. Think of digital equalizers, digital volume controls, upsamplers, digital pre-amplifiers, decoders for encoded signals on DVD etc. All those applications perform some mathematical operations on the digital audio signal. This in turn causes the wordlength of the signal to be increased. E.g. an input signal to an upsampler may have a wordlength of 16 bits (off a CD), but the output signal of the upsampler may have 24 bits or even more. This comes from the fact that the mathematical operations employed in such devices increase the word length. E.g. a multiplication of two 2 digit numbers results in a four digit number. So after the upsampler the word length may be higher than the subsequent processor may be able to accept. In this example, after the upsampler there may be a D/A converter with a 24 bit input word length capability. So if the upsampler generates a word length of more than 24 bits it should be dithered to 24 bits for maximum signal fidelity.

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I hope these excursions into the theory and practice of audio engineering have been useful for you.

If you would like to dive further into those issues I recommend to visit the website of Mr. Bob Katz, a renowned Mastering Engineer and a Weiss Engineering customer. He publishes articles on

Dithering and Jitter and many other topics at http://www.digido.com/

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THE JASON CD TRANSPORT

Features

Transport:

The Jason uses the renowned Philips CDPRO2M transport as its core unit.

Synchronization:

An internal high precision / low jitter clock generator generates all clocking signals, including those necessary for the CDPRO2M transport.

Digital Signal Processing:

The 44.1kHz / 16 Bit signal coming from the CDPRO2M can optionally be upsampled to 88.2 kHz or

176.4 kHz. The output level and the absolute phase of the audio signal (in phase / inverted) can be set. When upsampling is engaged or when the level is altered, the necessary mathematical operations inherently generate a signal which has a wordlength of more than the 16 bits coming from the CD. In that case the output wordlength can be selected to be 16 or 20 or 24 bits in order to accommodate for the wordlength of the D/A converter connected to the JASON. The wordlength reduction to 16, 20 or 24 bits is done via the POW-R dithering algorithm. POW-R is the de-facto standard in professional audio for wordlength reduction. POW-R has been developed by the POW-R

Consortium LLC, where Weiss Engineering Ltd. is one of the four member companies.

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There is a "D/A Converter Enhancement" mode (DAC+ on the remote control unit). This mode helps to enhance the sonic quality of D/A converters connected to the JASON. DAC+ uses spread spectrum technology.

Try the DAC+ mode and leave it on or off as per your preference. With excellent D/A converters you should not be able to hear a difference between DAC+ mode on or off. With very poor D/A converters other detrimental effects may be stronger and thus no difference between DAC+ on or off can be heard either.

Outputs:

The Jason has a plethora of output connectors. There are RCA and Toslink outputs which operate at a constant 44.1kHz sampling rate independent of the setting of the upsampler. There are XLR,

RCA, BNC and ST optical connectors which supply the 44.1 / 88.2 / 176.4 signal as implied by the setting of the upsampler. Then there are two XLR connectors for dual wire connection to the D/A

Converter. That dual wire output operates at 88.2 or 176.4 kHz only. At 44.1kHz it is muted.

Power Supply:

A powerful non-switching power supply is used. All sensitive voltages have their own regulators.

The power switch activates a semiconductor relais which only switches on or off at zero crossings of the mains voltage. This assures a glitch free power switching.

Mechanical Design:

The JASON employs a twin metal frame. The inner chassis is made of steel and acts as a very effective shield against electrostatic and electromagnetic radiation. The outer frame is made of massive anodized aluminium for additional shielding, resulting in optimal heat convection and beautiful looks. The four feet have been designed for optimum vibration and shock absorption.

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Frontpanel elements:

Five switches for skip backward, skip forward, stop, play/pause and lid open/close.

A high resolution graphical display.

A power switch.

Backpanel elements from left to right:

USB connector for software download (for future software upgrades).

RCA and Toslink connector for fixed sampling rate 44.1kHz output.

RCA, ST optical, BNC, XLR connectors for single wire 44.1 / 88.2 / 176.4 kHz output.

2 XLR connectors for dual wire 44.1 / 88.2 / 176.4 kHz output.

Mains connector with fuses and voltage selector.

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Operation

Unpacking and setup of the JASON

Carefully unpack the JASON. The following items should be enclosed:

The JASON CD Transport unit

A Remote Control unit

A product registration card

This Owners Manual

A Certificate of Guarantee

The JASON should be placed horizontally on a plane surface. Make sure that there is enough space above the unit such that the lid can open freely.

Mains Connection

Before connecting the mains cable make sure the voltage selector switch on the back of the unit

(integrated into the mains connector) is set to the appropriate voltage. If this is not the case then open the mains selector lid with a strong screwdriver. The mains plug must not be plugged into the connector for that purpose. Now you see a black selector drum with appropriate voltages written in white letters. Remove this drum, turn it to the appropriate voltage and reinsert it. Now firmly close the lid again. Connect the JASON to the wall outlet with the mains cable.

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Output Connection

Depending on the D/A Converter you connect, you need to set up the JASON. First you need to know some technical information about your D/A converter, namely the sampling rates it is able to operate at, the wordlength it is capable to accept at its input and the kind of connectors it has.

Here is a guide for all kinds of D/A variants. The numbers refer to the numbers printed on the backpanel of the JASON to designate the output connectors.

Connection of the Weiss MEDEA D/A Converter:

If you would like to operate the MEDEA at either 44.1 kHz or 88.2 kHz use the JASON output 2 or 4 to connect the MEDEA. Both balanced (XLR, output 2) or unbalanced (RCA, output 4) are fine for that purpose. (I, personally, recommend to use the XLR output.) On the remote control set the sampling rate to 44.1kHz or 88.2kHz and the output wordlength to 24 bit. You may experiment with the sampling rate, maybe you prefer the sound of one over the other.

If you like to operate the MEDEA at 176.4kHz you have to use ouput 1 of the JASON. Connect the

"left" connector to input number 1 on the MEDEA and the "right" connector to input number 2 on the MEDEA. Select input number 1 on the MEDEA. On the remote control set the sampling rate to

176.4kHz and the output wordlength to 24 bit. The MEDEA now automatically detects the 176.4kHz sampling rate / dual wire format and lights both LEDs at input 1 and 2.

You may also connect the MEDEA for 176.4kHz operation and at the same time connect JASON output 2 or 4 to the MEDEA input 3 or 4. This allows to select 44.1 or 88.2 kHz sampling rates at the JASON (using MEDEA input 3 or 4) or the 176.4 kHz sampling rate (using MEDEA input 1).

For third party D/A Converters:

D/A operates up to 44.1kHz, not at 88.2 or 176.4:

Use ouput 2, 3, 4, 5, 6 or 7. On the remote control set the sampling rate to 44.1kHz and the output wordlength to the maximum number of bits your D/A converter is capable to convert. E.g. if it is designated to be a "20 Bit converter" then set the output wordlength to 20 bits.

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D/A operates up to 88.2kHz, not at 176.4:

Use ouput 1, 2, 3, 4 or 5. Output 1 is the dual wire output. Use this only if your D/A converter is designed to accept a dual wire signal. On the remote control set the sampling rate to 44.1kHz or

88.2kHz and the output wordlength to the maximum number of bits your D/A converter is capable to convert. E.g. if it is designated to be a "20 Bit converter" then set the output wordlength to 20 bits. You may experiment with the sampling rate, maybe you prefer the sound of one over the other.

D/A operates up 176.4kHz:

Use ouput 1, 2, 3, 4 or 5. Output 1 is the dual wire output. Use this only if your D/A converter is designed to accept a dual wire signal. On the remote control set the sampling rate to 44.1kHz or

88.2kHz or 176.4kHz and the output wordlength to the maximum number of bits your D/A converter is capable to convert. E.g. if it is designated to be a "20 Bit converter" then set the output wordlength to 20 bits. You may experiment with the sampling rate, maybe you prefer the sound of one over the others.

First time power-up

After powering the unit, the JASON tries to read in a CD, but because there is no CD present it will show the message "no disc". Press the eject switch to open the lid. Now insert a CD, data surface down and press the eject switch again. The lid closes and the table of contents (TOC) of the CD is read. This takes a short while. After the TOC has been read press "play". The operation of the five switches on the frontpanel is straightforward. The skip forwards / backwards keys have a double function: When pressed and held down, the search forwards / backwards mode is engaged.

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The Remote Control

The JASON remote control sports the standard CD transport controls and in addition a few controls unique to the JASON CD transport.

To access the functions printed below the keys first press and hold the ALT key on the lower left and then press the second key. Note that the keypad can be locked / unlocked. For locking press ALT / mute. For unlocking press ALT / bright+. Also see the back of the remote control.

Key mute bright - / + phase 0° / 180°

Function mute all outputs, press again to unmute set the display brightness invert the absolute phase, normally set to 0° volume - / +

44.1k / 88.2k / 176.4k change the output volume select the sampling rate of the upsampler total / track select the type of time display (total of CD or

individual track) elapsed / remaining select the type of time display (elapsed time /

remaining time)

16 bit / 20 bit / 24 bit

DAC+ select the wordlength at the ouputs switch on/off the D/A Converter enhancement

The remaining keys are the standard CD transport control keys. The numerical keypad allows to enter track numbers directly.

The battery of the remote unit can be easily changed by removing the back cover.

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Technical Data

Digital Outputs:

4

5

6

7

Output

1

2

3

Connector type

(2) XLR

XLR

BNC

RCA

ST optical

RCA

Toslink

Format

AES/EBU dual wire

AES/EBU single wire

AES/EBU single wire

AES/EBU single wire

AES/EBU single wire

S/PDIF single wire

S/PDIF single wire

Available sampling rate(s) Available wordlengths

88.2 / 176.4 *) 16 / 20 / 24 bits

44.1 / 88.2 / 176.4

44.1 / 88.2 / 176.4

16 / 20 / 24 bits

16 / 20 / 24 bits

44.1 / 88.2 / 176.4

44.1 / 88.2 / 176.4

44.1 **)

44.1 **)

16 / 20 / 24 bits

16 / 20 / 24 bits

16 bits

16 bits

*) This output is muted at the 44.1 sampling rate

**) This is fixed at 44.1, independent of the sampling rate setting

DSP algorithms:

Upsampling, volume control, phase inversion, POW-R algorithm # 3 wordlength reduction (dithering).

Power:

Mains Voltage: 100...120 / 200...240 Volt

Fuse rating: 500 mA slow blow

Power consumption: 50VA max.

Power consumption in standby: 2VA max.

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OWNERS MANUAL FOR WEISS JASON CD TRANSPORT

CONTACT

Email:

Web:

For any questions, suggestions etc. feel free to contact us at:

Weiss Engineering Ltd.

Florastrasse 42

8610 Uster

Switzerland

Phone:

Fax:

+41 44 940 20 06

+41 44 940 22 14 [email protected]

http://www.weiss-highend.com

http://www.weiss.ch

Page:

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