Difference between revisions of "Audio analog connection"
JeanLouisN (Talk | contribs) (New page: Connecting a simple stereo headphone and a seprate microphone to the '''APF27_Dev''' requires no special precaution. But there are some more complex configurations which may cause the aud...) |
JeanLouisN (Talk | contribs) |
||
| Line 1: | Line 1: | ||
| − | Connecting a simple stereo headphone and a | + | Connecting a simple stereo headphone and a separate microphone to the '''APF27_Dev''' requires no special precaution. |
But there are some more complex configurations which may cause the audio output to refuse functioning with no visible cause, which are described below. | But there are some more complex configurations which may cause the audio output to refuse functioning with no visible cause, which are described below. | ||
{{Note| The problems described here do not occur with the '''APF51_Dev''', which has no audio virtual ground.}} | {{Note| The problems described here do not occur with the '''APF51_Dev''', which has no audio virtual ground.}} | ||
== Electrical background == | == Electrical background == | ||
| − | The output of an audio amplifier powered by a single positive voltage | + | The output of an audio amplifier powered by a single positive voltage presents normally a quiescent DC voltage of approximately half the power supply. |
This DC voltage should never be applied to a loudspeaker, so the classical wiring involves a series capacitor to block this DC voltage (two capacitors for a stereo amplifier). | This DC voltage should never be applied to a loudspeaker, so the classical wiring involves a series capacitor to block this DC voltage (two capacitors for a stereo amplifier). | ||
| Line 10: | Line 10: | ||
The capacitance value has to be large enough to preserve the lowest limit of the audio bandwidth (example : 220 uF for a 16 Ohm loudspeaker). | The capacitance value has to be large enough to preserve the lowest limit of the audio bandwidth (example : 220 uF for a 16 Ohm loudspeaker). | ||
| − | Another solution, avoiding the need | + | Another solution, avoiding the need for large capacitors, consists of creating a '''virtual ground''' for the speaker, the virtual ground being a DC voltage source with the same value as the quiescent voltage of the amplifier output. |
| − | + | In this context, the APF27_Dev board is designed to use the virtual ground available on the TS2101 audio chip. | |
The consequence is that the ground terminal of the audio output jack is connected to a 1.5V DC source (TS2101 VGND pin) instead of the board real ground. | The consequence is that the ground terminal of the audio output jack is connected to a 1.5V DC source (TS2101 VGND pin) instead of the board real ground. | ||
| Line 21: | Line 21: | ||
Here is an example of virtual ground short-circuit caused by the mains earth connection : | Here is an example of virtual ground short-circuit caused by the mains earth connection : | ||
| − | * the audio output of the APF27_dev is connected to a home stereo amplifier or any | + | * the audio output of the APF27_dev is connected to a home stereo amplifier or any other audio equipement having a mains plug with earth connection |
* the APF27_Dev has its ground connected to some equipement having a mains plug with earth connection, for example : | * the APF27_Dev has its ground connected to some equipement having a mains plug with earth connection, for example : | ||
** the development PC, through the RS232 cable | ** the development PC, through the RS232 cable | ||
Revision as of 17:45, 31 July 2011
Connecting a simple stereo headphone and a separate microphone to the APF27_Dev requires no special precaution.
But there are some more complex configurations which may cause the audio output to refuse functioning with no visible cause, which are described below.
 |
Note: The problems described here do not occur with the APF51_Dev, which has no audio virtual ground. |
Contents
Electrical background
The output of an audio amplifier powered by a single positive voltage presents normally a quiescent DC voltage of approximately half the power supply.
This DC voltage should never be applied to a loudspeaker, so the classical wiring involves a series capacitor to block this DC voltage (two capacitors for a stereo amplifier).
The capacitance value has to be large enough to preserve the lowest limit of the audio bandwidth (example : 220 uF for a 16 Ohm loudspeaker).
Another solution, avoiding the need for large capacitors, consists of creating a virtual ground for the speaker, the virtual ground being a DC voltage source with the same value as the quiescent voltage of the amplifier output.
In this context, the APF27_Dev board is designed to use the virtual ground available on the TS2101 audio chip.
The consequence is that the ground terminal of the audio output jack is connected to a 1.5V DC source (TS2101 VGND pin) instead of the board real ground.
 |
Warning: It is not permitted to connect this virtual ground to the real ground, this would short-circuit the 1.5V source and cause the TS2101 to enter the "short-circuit protection mode" and stop audio output operation (see P. 28 of the TS2101 data sheet). |
Ground loop via mains earth
Here is an example of virtual ground short-circuit caused by the mains earth connection :
- the audio output of the APF27_dev is connected to a home stereo amplifier or any other audio equipement having a mains plug with earth connection
- the APF27_Dev has its ground connected to some equipement having a mains plug with earth connection, for example :
- the development PC, through the RS232 cable
- the power supply (AC adaptor) itself
suggested workarounds :
- unplug the RS232 cable
- use a power supply with no earth connection
| |
Note: the Ethernet cable causes no ground loop, because it is isolated by transformers at both ends. |
Ground loop via the microphone jack
The audio input connector (microphone jack) of the APF27_Dev has its ground connected to the board's real ground.
Connecting together the grounds of both audio jacks causes a virtual ground short-circuit.
Examples :
- connecting the audio output and input to the same audio equipement, like an audio analog mixer
- connecting the audio output and input to a headset with microphone with common ground
suggested workaround :
- when both jacks are used, connect only the ground of the input jack, leaving the ground of the output jack unconnected
- then insert 2 capacitors in series with the audio outputs
