Texas Instruments PGA2505 Evaluation Module PGA2505EVM PGA2505EVM Hoja De Datos
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PGA2505EVM
4.5
Protection Network
4.6
Configurable Input Circuitry
4.7
Configurable Output Circuitry and Preamp Output Connector
1
2
3
Hot (+), to V
+
OUT
Cold ( ), to V
-
-
OUT
Shield, to GND
4.8
Host Interface
www.ti.com
Setup Guide
Resistors R
7
and R
8
, along with Schottky diodes D6 through D9, provide input protection for the PGA2505
preamplifier when using phantom power (during the turn-on phase), or when the input voltage exceeds the
VA+ or VA– power supplies by more than 350mV (the approximate turn-on voltage of the Schottky
diodes). Zener diodes D10 and D11 are provided to protect the VA+ and VA– power supplies from
exceeding the absolute maximum supply voltage.
VA+ or VA– power supplies by more than 350mV (the approximate turn-on voltage of the Schottky
diodes). Zener diodes D10 and D11 are provided to protect the VA+ and VA– power supplies from
exceeding the absolute maximum supply voltage.
A common fault condition is for either the hot (+) or cold (–) input of the preamplifier to be shorted to
ground. With phantom voltage applied, this configuration will cause the blocking capacitors to discharge,
with a large surge current presented at the PGA2505 input pins. Without the protection network, the
PGA2505 would be permanently damaged by the surge current, which can reach several amperes in peak
magnitude. The Schottky diodes are forced into conduction during this fault condition, steering most of the
charge away from the PGA2505 device and towards the power supplies. The series resistors can be set to
a value that will help limit the input current, although care must taken to avoid adding too much resistance,
because the added noise can degrade the overall performance of the preamplifier.
ground. With phantom voltage applied, this configuration will cause the blocking capacitors to discharge,
with a large surge current presented at the PGA2505 input pins. Without the protection network, the
PGA2505 would be permanently damaged by the surge current, which can reach several amperes in peak
magnitude. The Schottky diodes are forced into conduction during this fault condition, steering most of the
charge away from the PGA2505 device and towards the power supplies. The series resistors can be set to
a value that will help limit the input current, although care must taken to avoid adding too much resistance,
because the added noise can degrade the overall performance of the preamplifier.
The Schottky diodes add a nonlinear capacitance to the input circuit, which can result in additional
distortion. However, with the relatively small input voltage swing present when the preamplifier is set to
gains between 9dB and 60dB, the effect on the THD+N of the PGA2505 is small or negligible. For
unity-gain applications, where the voltage swing may become large enough in magnitude to transition over
a greater portion of the diodes nonlinear capacitance, the THD+N ratio may degrade by as much as 3dB
from the published typical performance specifications.
distortion. However, with the relatively small input voltage swing present when the preamplifier is set to
gains between 9dB and 60dB, the effect on the THD+N of the PGA2505 is small or negligible. For
unity-gain applications, where the voltage swing may become large enough in magnitude to transition over
a greater portion of the diodes nonlinear capacitance, the THD+N ratio may degrade by as much as 3dB
from the published typical performance specifications.
The configurable portion of the input circuit includes R
5
, R
6
, R
10
, R
11
, R
14
, R
15
, C
C1
, C
C2
, and jumper
JMP2. These components support the prototyping of additional circuitry, such as pads and filters. During
assembly at the factory, resistors R
assembly at the factory, resistors R
5
and R
6
are not installed, while R
10
, R
11
, R
14
, R
15
, C
C1
, and C
C2
are
replaced by wire shunts.
The configurable portion of the output circuit includes R
1
, R
2
, R
3
, R
12
, R
13
, C
23
, C
24
, and C
25
. These
components support prototyping of additional circuitry, such as pads and filters, as well as the emulation
of various loading conditions. During assembly at the factory, resistors R
of various loading conditions. During assembly at the factory, resistors R
12
and R
13
are replaced by wire
shunts. Resistors R
1
through R
3
, as well as capacitors C
23
through C
25
, are not installed.
The differential preamplifier output is provided at connector J3, which is a 3-pin male XLR connector.
illustrates the pin connections for connector J3.
Figure 6. Preamp Output Connector Configuration
The PGA2505EVM supports an external host interface to the PGA2505 serial port using connectors J5
through J7. A PC parallel port may be connected to connector J5, using the straight-through cable
supplied with the EVM package. The PC parallel port is used as the communications interface for the
applications software provided with the EVM.
through J7. A PC parallel port may be connected to connector J5, using the straight-through cable
supplied with the EVM package. The PC parallel port is used as the communications interface for the
applications software provided with the EVM.
provides details for installing and using the
applications software.
The DATA_IN header (J6) may be used as an alternative host interface connection, and is designed
primarily for interfacing to microprocessors, digital signal processors, or other host devices in either end
equipment or hardware development platforms.
primarily for interfacing to microprocessors, digital signal processors, or other host devices in either end
equipment or hardware development platforms.
The DATA_OUT header (J7) is designed primarily for cascading multiple PGA2505EVM boards in a
daisy-chain fashion. Daisy-chaining is described in more detail in the PGA2505 product data sheet.
daisy-chain fashion. Daisy-chaining is described in more detail in the PGA2505 product data sheet.
SBOU078 – June 2009
PGA2505EVM
9