These "some 1 uF caps on supply pins" are the key point to get this chip working correctly at all. It is stated clearly about it in the reference design... 😉
in single ended mode - yes.
In bridged mode (BTL, PBTL, AD or BD modulation) each input pin is a input for separate (paralleled) half bridge. So to get full power output, it is needed to feed a differential signal to the input pins.
In bridged mode (BTL, PBTL, AD or BD modulation) each input pin is a input for separate (paralleled) half bridge. So to get full power output, it is needed to feed a differential signal to the input pins.
yes ,
It will be of great help if you could give inverted images in pdf format,for photoresist developing.
thank you and regards
Thank you For the file. Can you please tell what is the size of pcb, As i have to copy the file to corel draw to invert it for photo resist method
A ground planeis paramount for a design like this, it is critical for keeping noise down, and for providing low inductance reture for the high current switching, that means a minimum two layer board. !!
Don't mean to hijack this thread... I built one of these amps based on the TI EVM PHD version (I used TI's Gerbers and had boards made). I built one up (not for the faint of heart - there are many, many components, most of them 0603). I made a laser cut solderpaste stencil and placed the parts using tweezers under a microscope. I have an SMD oven that I built for soldering (mandatory on this PCB, no way you can do a decent job by hand and I've been soldering SMD for 20 years). I hand wound the inductors (fun!) though subsequently I got some samples from a couple of companies in China. It fired up and worked perfectly the first time. This is one great amp. I don't have any audio test equipment (just Tek 2245A and Tek MSO2024 scopes). I did see a little bit of "furriness" on the output but I *almost* think this was a result of bad scope probing and not the amp. In a completely non-technical test I shorted the input to ground and could hear nothing (not a thing) from the speakers. With a Line 6 POD as the input and turned up all the way there was an "almost" barely audible bit of noise if you put your ear to the speaker, however, I know this comes from the Line 6 unit.
I used a switching power supply from a company that specializes in "audio SMPS" though I also got some quotes from Chinese companies for 1/4 the price that had the same specs (I never got one to test though). Anyway, this is a killer amp. I used it for music and as a guitar amp (using the Line 6 "POD" as a "front end") and was very impressed.
I still have a couple of the PCB's, however the manufacturer "took liberties" with the largest holes. On one set of boards he made the heatsink and mounting holes the wrong side and on another the holes for the big terminals too small for the spec'd terminals used to connect to the board. I'm willing to sell what I have left for short money if the hole thing doesn't matter to you (I soldered wires directly to the pads or left the terminals sticking up).
As for the heatsink, I got an old one and machined it down to fit in the space provided. I had in mind a design to use a PC heatsink and fan like Gaurav did but after probing around a bit on the EVM I think the output traces get too long between the IC and the caps. I guess you could machine the PC heatsink so the caps can be near the IC. The placement and way these are connected are critical to making this thing work correctly. If you roll your own follow what TI did to the letter. CRANKING this thing and keeping the "clipping" led on constant it didn't even get warm to the touch. With the heatsink and fan(!) shown here I'm sure there may never be a heat problem. I also agree with Marce; a two sided PCB is really mandatory for this IC. When you see the waveforms and current paths on the board, there is no way a single-sided PCB can perform to the spec. If you plan on building one of these, know ahead of time it is a huge undertaking (just ordering components can be an ordeal). Getting the inductors right is critical. Placing all the parts took me three hours (though soldering takes 4 minutes in the oven so that's a push).
Good luck!
Mike T.
I used a switching power supply from a company that specializes in "audio SMPS" though I also got some quotes from Chinese companies for 1/4 the price that had the same specs (I never got one to test though). Anyway, this is a killer amp. I used it for music and as a guitar amp (using the Line 6 "POD" as a "front end") and was very impressed.
I still have a couple of the PCB's, however the manufacturer "took liberties" with the largest holes. On one set of boards he made the heatsink and mounting holes the wrong side and on another the holes for the big terminals too small for the spec'd terminals used to connect to the board. I'm willing to sell what I have left for short money if the hole thing doesn't matter to you (I soldered wires directly to the pads or left the terminals sticking up).
As for the heatsink, I got an old one and machined it down to fit in the space provided. I had in mind a design to use a PC heatsink and fan like Gaurav did but after probing around a bit on the EVM I think the output traces get too long between the IC and the caps. I guess you could machine the PC heatsink so the caps can be near the IC. The placement and way these are connected are critical to making this thing work correctly. If you roll your own follow what TI did to the letter. CRANKING this thing and keeping the "clipping" led on constant it didn't even get warm to the touch. With the heatsink and fan(!) shown here I'm sure there may never be a heat problem. I also agree with Marce; a two sided PCB is really mandatory for this IC. When you see the waveforms and current paths on the board, there is no way a single-sided PCB can perform to the spec. If you plan on building one of these, know ahead of time it is a huge undertaking (just ordering components can be an ordeal). Getting the inductors right is critical. Placing all the parts took me three hours (though soldering takes 4 minutes in the oven so that's a push).
Good luck!
Mike T.
Hello 81bas... could you give some examples of those critical places that you spoke about because i just taught it has to be linked to the ground and that's all 🙁
regards,
savu
Hi! please see in http://focus.ti.com/lit/ds/symlink/tas5630.pdf at pages 25 and 26. These places/traces are marked with color arrows and bulbs...
As a small hint: the GND pins in this IC are NOT connected internally (in both DKD and PHD versions). So any smallest GND trace inductivity will produce huge voltage spikes between GND pins, which will definitely kill the IC...
yes it is working good, but i tried it only upto 26volts since no higher supply was with me that time.
OK ty jash, i order the tas5630 to Texas instrument and im looking for a good pcb to test this chips.
PCB for TAS5630
Going to order for manufacturing the EVM PCB -PHD (Easy to Sold ) from a manufaturer in DELHI.
It is going to cost me around 25$/PC.
If anyone interested then let me know on mail ID nalin.bhasker@yahoo.co.in.
Going to order for manufacturing the EVM PCB -PHD (Easy to Sold ) from a manufaturer in DELHI.
It is going to cost me around 25$/PC.
If anyone interested then let me know on mail ID nalin.bhasker@yahoo.co.in.
I am going to order for EVM 5630 PHD PCBs. Cost would be 25$/ Pc. If anyone is interested let me know at nalin.bhasker@yahoo.co.in.
PCBs are available . http://www.diyaudio.com/forums/swap-meet/210252-tas5630-dkd-phd-evm-pcb-sale.html
25$ ?
why dont you try some PCB manufacturers like PCBPower. you have all the layouts in the evaluation pdf.
this is much cheaper.
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