Konnichiwa,
Question is, will it fit the PCB? Otherwise sounds fine.
Yes, this has been the same since the CD-720/CD-36 (Philips/Marantz respectively) through all the versions.
I am not sure if the 723 now has a real crystal, the 720 used a (slightly) cheaper ceramic resonator.
My upgrades where LM6182 in the analogue stage (with the required upgrades in the PSU) new clock, seperate powersupplies (4pcs) for clock, dac and +/- Analog stage, -rm-rf the headphone section.
I eventually tried a 500VA external torroid transformer for the analogue powersupply it did give another little upgrade ove the internal 25VA EI Transformers I used origianlly.
That modded 720 was a tough customer!!!!
Sayonara
ash_dac said:
Question is, will it fit the PCB? Otherwise sounds fine.
ash_dac said:Thanks for the pointers towards upgrading the power supply. I thought I misread the diagrams at first (+10/-10V supply for opamps was unregulated) but nope it's all there!
Oh dear
Yes, this has been the same since the CD-720/CD-36 (Philips/Marantz respectively) through all the versions.
I am not sure if the 723 now has a real crystal, the 720 used a (slightly) cheaper ceramic resonator.
My upgrades where LM6182 in the analogue stage (with the required upgrades in the PSU) new clock, seperate powersupplies (4pcs) for clock, dac and +/- Analog stage, -rm-rf the headphone section.
I eventually tried a 500VA external torroid transformer for the analogue powersupply it did give another little upgrade ove the internal 25VA EI Transformers I used origianlly.
That modded 720 was a tough customer!!!!
Sayonara
-- http://myweb.tiscali.co.uk/nuukspot/decdun/project.cd2.html#cdstarting2
So, from where can I get a service manual then? Not good enoug in English to call 'em :-/
Moin,
everybody interested in the service manual for the CD723 (713)
send me an email with your email-adress.
The pdf-size is 7,9mb.
Carsten
everybody interested in the service manual for the CD723 (713)
send me an email with your email-adress.
The pdf-size is 7,9mb.
Carsten
carawu said:
*Bump*
Anyone in possession of this pdf?
Carawu didn't respond to my emails :-(
I know bumping is evill and all that, but, I haven't been able to find it elsewhere.
I´m sorry,
but there is no email of you in my inbox or spamfolder.
I´ll try to send you an email.
Carsten
but there is no email of you in my inbox or spamfolder.
I´ll try to send you an email.
Carsten
I got your email, sent a response, and I got backsome obscure error from your mail provider(I think.)
Anyhow, would you mind sending me the manual to my email adress:jann.ove@gmail.com?
Jann - Ove
Anyhow, would you mind sending me the manual to my email adress:jann.ove@gmail.com?
Jann - Ove
Hello Jann - Ove,
I didn´t understand the reason for our problem...but I send you the manual. Did you get it?
Carsten
I didn´t understand the reason for our problem...but I send you the manual. Did you get it?
Carsten
I got the manual now 🙂
Last time I tried to reply to your email, and got some obscure mail back from gmx.net, apparently gmx.net don't like me :-(
But, thanks anyway.
Last time I tried to reply to your email, and got some obscure mail back from gmx.net, apparently gmx.net don't like me :-(
But, thanks anyway.
Kuei Yang Wang said:
Hi,
So that's the Vdd dealt with which is a large chunk of that equation from the tda1545a datasheet now to the resistors!
For the reference resistors (R3 and R4) I assume I choose precision 0.1% resistors with 'good' temperature coefficients ?
Some calculations:- (warning these may need correcting)
Ibias = Iref X Abias
So from the datasheet 714ua / 9.42 = 75.80ua needed for Iref.
From the resistors used in the datasheet:-
11K / (33K+22K+11K) x 5v = gives 0.83V across internal 11K Rref
(0.83/11000) X 1000000=75.46ua Iref
Trying 14.6K, 7.4K....
14.6K / (33K + 22K + 14.6K) X 5 =gives 1.04V across internal 14.6K Rref
(1.04/14600 )x 1000000= 71.23ua Iref
7.4K /(33K +22K +7.4K) X 5 = gives 0.59V across internal 7.4K
(0.59/7400) X 1000000 = 79.73ua Iref
Well done Philips give people like me practice in building power supplies 🙂
The datasheet says ,"Easy application: single 3 to 5.5 V rail power supply and output- and bias current are proportional to the supply voltage"
Says it all really!
I guess setting vref at 1/2 vdd with passive i/v (see link) you get more current output across the output resistors pushing the output voltage out of compliance causing distortion.
http://diyparadise.com/dackit/1545dackit.html
Please correct me on my calc's if i am wrong.
Kind regards,
Ashley.
Understanding the tda1545a...
Hi,
For those interested in the tda1545a continuous calibration technique....
http://www.utdallas.edu/~hellums/docs/EE7326/SelfCalDAC.pdf
I can understand bits of the paper but most of it is beyond me!
Kind regards,
Ashley.
Hi,
For those interested in the tda1545a continuous calibration technique....
http://www.utdallas.edu/~hellums/docs/EE7326/SelfCalDAC.pdf
I can understand bits of the paper but most of it is beyond me!
Kind regards,
Ashley.
Can you send me this service manual, please? I have no permission to write you @emeil, i dont know why.carawu said:
My @emeil is aivarasrutkauskas@yahoo.com
Carsten,
Please send me CD723 manual also - can't send you email - your email is blocked by admin?
John
Please send me CD723 manual also - can't send you email - your email is blocked by admin?
John
service manual od cd 723
hi im also looking for the service manual of philips cd723 if you can send me it will be a great help to me coz im starting to mod my player and cant find the muting resistor for this cd player...thanks in advance....heres my email; abiedoodles@yahoo.com
hi im also looking for the service manual of philips cd723 if you can send me it will be a great help to me coz im starting to mod my player and cant find the muting resistor for this cd player...thanks in advance....heres my email; abiedoodles@yahoo.com
Hello,
the manual is online now:
http://www.audioamp.kylos.pl/audio/downloads/cd/cd723.zip
and read this:
http://myweb.tiscali.co.uk/nuukspot/decdun/project.cd2.html
Carsten
the manual is online now:
http://www.audioamp.kylos.pl/audio/downloads/cd/cd723.zip
and read this:
http://myweb.tiscali.co.uk/nuukspot/decdun/project.cd2.html
Carsten
There is probab. a simple answer for this question but I'm too lazy to search 😉 ...
For Vref (Iref), Philips, in the datasheet schematic, suggests a 2/3 Vdd voltage divided be created using 22k and 33k resistors.
Given the small voltage (<5vdc) and currents in this topology, why are THESE relatively "high"-value resistors suggested (as opposed to lower values)?
E.g., is it better damping?
Etc...
For Vref (Iref), Philips, in the datasheet schematic, suggests a 2/3 Vdd voltage divided be created using 22k and 33k resistors.
Given the small voltage (<5vdc) and currents in this topology, why are THESE relatively "high"-value resistors suggested (as opposed to lower values)?
E.g., is it better damping?
Etc...
An externally hosted image should be here but it was not working when we last tested it.
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The resistor values are high because the internal resistor of the 1545 is also relatively high (11k nominal). So the divider resistors are chosen to give 1/6th of the supply voltage across the internal resistor, at the nominal value. However it has a fairly wide tolerance.
Its possible to use lower value resistors but then you'd need to put a resistor in parallel with the internal one (pin7 to pin4) to shunt a proportion of the current away. Can't see any value in that though - you'd also need a larger value of decoupling cap (C2 in your schematic) to achieve similar PSRR.
<edit> I just realized this was assuming 1mA output current - the DAC will accept up to 2mA, when there will be 1/3rd of the supply across the internal 11k, corresponding to 1.66V nominally.
Its possible to use lower value resistors but then you'd need to put a resistor in parallel with the internal one (pin7 to pin4) to shunt a proportion of the current away. Can't see any value in that though - you'd also need a larger value of decoupling cap (C2 in your schematic) to achieve similar PSRR.
<edit> I just realized this was assuming 1mA output current - the DAC will accept up to 2mA, when there will be 1/3rd of the supply across the internal 11k, corresponding to 1.66V nominally.
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I wasn't too sure that "internal" R_ref=11k -- shown in Fig. 1 -- was real or a parallel equivalence.
That is, in the DS (pg. 9, Note #5), it states:
R3=R4=11k
...and this supposedly gives the highest S/N in the parametric table above that Note.
I have no idea what Note 5 means with that remark R3=R4=11k.
Also, a bit weird (as are a LOT things about this DS and 1545 device!!) is putting a fixed-value R (R_ref, 11k, if that's a real resistor) *inside* the device where a developer has no control (esp. WRT to quality, e.g., tolerance, metal film, etc.)
EDIT: I measured a naked TDA1545a (it is a "true"/genuine/OEM Philips chip, AFAICT, w/o "TAIWAN" label) at Pin 7 WRT Ground (pin 4) using a Fluke 87 DMM:
10.15k-ohm
That is, in the DS (pg. 9, Note #5), it states:
R3=R4=11k
...and this supposedly gives the highest S/N in the parametric table above that Note.
I have no idea what Note 5 means with that remark R3=R4=11k.
Also, a bit weird (as are a LOT things about this DS and 1545 device!!) is putting a fixed-value R (R_ref, 11k, if that's a real resistor) *inside* the device where a developer has no control (esp. WRT to quality, e.g., tolerance, metal film, etc.)
EDIT: I measured a naked TDA1545a (it is a "true"/genuine/OEM Philips chip, AFAICT, w/o "TAIWAN" label) at Pin 7 WRT Ground (pin 4) using a Fluke 87 DMM:
10.15k-ohm
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Another thing ...
If one is using NON-DIFFERENTIAL inputs on the OP, as in the case of popular Rudolf I/V stage, then there no (+) OP1 and OP2 input for V_ref to connect to (see DS, Fig. 1). V_ref, hence, "sees" infinite resistance/impedance.
In this case, I wonder if it's not helpful to have SOMETHING for V_ref to sink to -- i.e., a very-high-value R, or even a snubber ?
If one is using NON-DIFFERENTIAL inputs on the OP, as in the case of popular Rudolf I/V stage, then there no (+) OP1 and OP2 input for V_ref to connect to (see DS, Fig. 1). V_ref, hence, "sees" infinite resistance/impedance.
In this case, I wonder if it's not helpful to have SOMETHING for V_ref to sink to -- i.e., a very-high-value R, or even a snubber ?
R_ref and datasheet V_ref (I_ref) R3, R4
R3=22k, R4=33k ...
V_dd to GND=64k
I_ref (pin 7) to GND=9.5k
V_dd to I_ref (pin 7)=55k (or: 22k + 33k, as expected)
V_ref to GND=41.5k
...and with unpowered 1545 per the datasheet ckt (Fig. 1), using
R3=22k, R4=33k ...
V_dd to GND=64k
I_ref (pin 7) to GND=9.5k
V_dd to I_ref (pin 7)=55k (or: 22k + 33k, as expected)
V_ref to GND=41.5k
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