CIRRUS CDB5466U

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CDB5466U
CDB5466U Evaluation Board
Features
General Description
The CS5466 is a low cost power/energy IC with pulse
output for power measurement solutions. The
CDB5466U Evaluation Board is an inexpensive tool
designed to evaluate the functionality and performance of the CS5466.
Active Energy-to-Pulse Conversions
Simple Configuration Jumpers
– Current Channel Gain
– High-pass Filter
– Energy-to-pulse Output Frequency
The evaluation board is designed to output energy-topulse conversions upon power-up. The CS5466 data
sheet should be read and consulted when using the
CDB5466U evaluation board.
Energy Pulses
– Collected by On-board Microcontroller
– Available on External Header
– Viewable via LEDs
The evaluation board includes a microcontroller with a
USB interface. The microcontroller and GUI (Graphical User Interface) provide a means to quickly register
and evaluate the CS5466’s energy-to-pulse outputs.
Multiple Supply Voltage Selections
USB Communication with PC
ORDERING INFORMATION
CDB5466U
Evaluation Board
On-board Voltage Reference
+5V
GND
Vu+ EXT
VD+ EXT
4.096MHz
XIN
VIN+
XOUT
VIN+
VIN-
IIN+
IIN+
IIN-
IINVREFIN
VIN-
VREFOUT
CS5466
E1
E2
FOUT
NEG
E1
E2
FOUT
NEG
C8051F320
Microcontroller
USB
HPF
IGAIN0
IGAIN1
FREQ0
FREQ1
FREQ2
CONFIGURATION JUMPERS
VREF SOURCE
REF+
+2.5 V
Reference
http://www.cirrus.com
Copyright © Cirrus Logic, Inc. 2005
(All Rights Reserved)
MAY ‘05
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CDB5466U
TABLE OF CONTENTS
1.
2.
3.
4.
LIST OF FIGURES .................................................................................................................... 2
LIST OF TABLES ...................................................................................................................... 2
HARDWARE ............................................................................................................................. 3
1.1 Introduction ........................................................................................................................ 3
1.2 Evaluation Board Overview ................................................................................................ 3
1.2.1 Analog Section ...................................................................................................... 4
1.2.2 Digital Section ....................................................................................................... 5
1.2.3 Power Supply Section ........................................................................................... 8
SOFTWARE .............................................................................................................................. 9
2.1 Installation Procedure ........................................................................................................ 9
2.2 Using the Software ............................................................................................................. 9
2.2.1 Start-Up Window ................................................................................................... 9
2.2.2 CS5466 Pulse Rate Output Window ................................................................... 11
SCHEMATICS ........................................................................................................................ 13
LAYOUT ................................................................................................................................. 18
LIST OF FIGURES
Figure 1. CDB5466U Assembly Drawing ........................................................................................ 3
Figure 2. CDB5466U Start-up Window ........................................................................................... 9
Figure 3. Alert Window .................................................................................................................. 10
Figure 4. Quit Window................................................................................................................... 10
Figure 5. CDB5466 Evaluation Board ........................................................................................... 11
Figure 6. CDB5466U Pulse Rate Output Window......................................................................... 11
Figure 7. Analog Inputs ................................................................................................................. 13
Figure 8. CS546x and Socket ....................................................................................................... 14
Figure 9. CS5462 and CS5466 Configuration............................................................................... 15
Figure 10. Microcontroller and USB Interface ............................................................................... 16
Figure 11. Power Supply ............................................................................................................... 17
Figure 1. Silk Screen ..................................................................................................................... 17
Figure 1. Topside Layer ................................................................................................................ 18
Figure 1. Bottomside Layer ........................................................................................................... 19
LIST OF TABLES
Table 1. Voltage Reference Selection for VREF ............................................................................. 4
Table 2. Voltage Reference Selection for VREF ............................................................................. 4
Table 3. Voltage and Current Channel Input Signal Selection ........................................................ 5
Table 4. Current Channel PGA Selection........................................................................................ 6
Table 5. HPF Option Selection........................................................................................................ 6
Table 6. Energy Output Frequency ................................................................................................. 7
Table 7. Power Supply Connections ............................................................................................... 8
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1. HARDWARE
1.1
Introduction
The CS5466 is a low cost power measurement solution combining two ∆Σ analog-to-digital converters (ADCs), an
energy-to-frequency converter, and energy pulse outputs on a single chip. It is designed to accurately measure and
calculate energy for single phase, 2- or 3-wire power metering applications with minimal external components.
Low-frequency energy outputs, E1 and E2 supply average active power and can be used to drive a stepper motor
or a mechanical counter; the high-frequency energy output FOUT is designed to assist in calibration; and NEG indicates negative energy.
The CS5466 has configuration pins which allow the selection of pulse output frequency, current channel input range,
and the high-pass filter enable option. The CS5466 also has a power-on reset function which holds the part in reset
until the supply reaches the proper level. The CDB5466U is shipped with a CS5466-ISZ device located at U6.
1.2
Evaluation Board Overview
The CDB5466U evaluation board provides a quick path to evaluating the CS5466 Power Measurement IC. Figure
1 illustrates the placement of the terminals, jumpers and IC components. The jumper options are shown in the factory default positions.
GND
J3
VD+_EXT
J4
Vu+_EXT
J5
JTAG
USB
J6
J1
JP1
J2
TP1 TP2
TP3
GND
8051_REGIN
Vu+_EXT
+5V
VD+
J9
JP2
VD+
VD+_EXT
+5V
+3.3V
GND
VD+
J8
U4
TP4
TP5
U3
8051
+5V
TP6
GND
J14
RESET
GND
J12
XOUT XIN
TP7
J23
J27
GND
IIN+
IINGND
GND
VREF
IIN+
IINVREF
GND
JP6
GND
1 LED_EN
NEG
Y1
GND
J16
GND
U5
CPUCLK
TP10
5466
VIN+
TP9
J15
JP4
TP11
VINJ22
J24
IIN+
TP12
J25
VA+GND
VREF
VREFIN
VREFOUT
GND
FOUT
J11
E1
E2
FOUT
NEG
RESET
U7
J17
VIN-
LED_EN
1
TP8
4.096MHz
GND
VREF
VIN+
VINVREF
GND
VIN+
E2
J13
CDB5466U REV X
GND
GND
E1
LED_EN
1
LT1019
REF+
REF+
LED_EN
1
J10
EXT ENER REG
S1
JP3
JP5
GND VD+
GND
J28
J29
J30
J31
J32
J33
VD+
FOUT
GND
TP13
IINJ26
FREQ2 FREQ1 FREQ0 IGAIN1 IGAIN0
HPF
CS5466 CONFIG
Figure 1. CDB5466U Assembly Drawing
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CDB5466U
The CDB5466U evaluation board is partitioned into two main sections - analog and digital. The analog section consists of the CS5466 and a precision voltage reference that operates from a single +5 V power supply. The digital
section consists of the microcontroller, the reset circuitry, and the USB interface. The digital section can operate from
a +5 V or +3.3 V power supply. The evaluation board is epuipped with power supply connections that accommodate
all of the various supply options of the CS5466.
The evaluation board is designed to output energy-to-pulse conversions upon power-up. Software that runs on a PC
provides a GUI (Graphical User Interface) as a means to quickly register and evaluate the CS5466’s energy-to-pulse
outputs. To accomplish this, the board comes equipped with USB drivers and cable which physically interfaces the
evaluation board to the PC. The software provides easy access to the energy outputs E1, E2, and FOUT and provides a means to display and evaluate the performance of the CS5466.
1.2.1
Analog Section
The CDB5466U evaluation board provides screw-type terminals (J23 and J27) to connect input signals to the voltage and current channels. The screw terminals are labeled as VIN+, VIN-, IIN+, and IIN-. A simple R-C network at
each channel input provides a simple anti-alias filter.
The evaluation board provides three voltage reference options for VREFIN to the CS5466. The three voltage reference options include: VREFOUT from the CS5466, the on-board +2.5 V reference, and external REF+ (screw terminal J14). Table 1 and Table 2 illustrate the options available for VREFIN. With a jumper on J25 in the position
Reference
Description
J25
VREFOUT
Selects on-Chip
Reference (25ppm/°C)
VREF O
VREFIN O
VREFOUT
(Default)
VREF
Selects External or
LT1019 Reference(J12)
VREF O
VREFIN O
VREFOUT
Table 1. Internal Voltage Reference Selection for VREF
labeled VREFOUT, the reference is supplied by the on-chip voltage reference. With a jumper on J25 in the position
labeled VREF, the reference is supplied by an off-chip voltage reference.
Table 2 illustrates the options available for VREF. With a jumper on J12 in position LT1019, the LT1019 provides a
Reference
Description
J12
LT1019
Selects on-Board
LT1019 Reference
(5ppm/°C)
LT1019
REF+
O
O
O
VREF
VREF
REF+
Selects External
Reference Source
(J6)
LT1019
REF+
O
O
O
VREF
VREF
(Default)
Table 2. External Voltage Reference Selection for VREF
+2.5 V reference (the LT1019 was chosen for its low drift - typically 5ppm/°C). By setting the jumper on J12 to position REF+, an external voltage reference is supplied via screw terminal J14’s REF+ input.
The three input signal options for the voltage (VIN±) and current (IIN±) channel input include: an external signal
(screw terminals J23 and J27), GND or VREF. Table 3 illustrates the options available. By installing jumpers on J17
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to position VIN+, J22 to position VN-, J24 to position IIN+ and J26 to position IIN-, the input voltage signal is supplied
from the screw terminals J23 and J27. With a jumper on J17, J22, J24 and J26 in the GND position, the inputs are
connected to analog ground (AGND). With a jumper on J17, J22, J24 and J26 in position VREF, the inputs are connected to the reference voltage selected on J12.
INPUT
Description
VIN± or IIN±
Selects External
Signal
J17
GND
VREF
VIN+
O
O
O
O
O
J22
VIN+
VIN+
VIN+
VINVREF O
GND O
(Default)
O
O
O
J24
VINVINVIN-
GND
VREF
IIN+
(Default)
O
O
O
O
O
J26
IIN+
IIN+
IIN+
IINVREF
GND
(Default)
O
O
O
O
O
IINIINIIN-
(Default)
O
O
O
O
O
VIN+
VIN+
VIN+
VINVREF
GND
O
O
O
O
O
VINVINVIN-
GND
VREF
IIN+
O
O
O
O
O
IIN+
IIN+
IIN+
IINVREF
GND
O
O
O
O
O
IINIINIIN-
Selects Grounding
the Input
GND
VREF O
VIN+ O
O
O
O
VIN+
VIN+
VIN+
VINVREF O
GND O
O
O
O
VINVINVIN-
GND
VREF
IIN+
O
O
O
O
O
IIN+
IIN+
IIN+
IINVREF
GND
O
O
O
O
O
IINIINIIN-
Selects Reference
Source
GND
VREF
VIN+
O
O
O
VIN+
VIN+
VIN+
VINVREF
GND
O
O
O
VINVINVIN-
GND
VREF
IIN+
O
O
O
O
O
IIN+
IIN+
IIN+
IINVREF
GND
O
O
O
O
O
IINIINIIN-
VIN± or IIN±
Selects External
Signal
GND
VREFIN
GND
VREF
VIN+
O
O
O
O
Table 3. Voltage and Current Channel Input Signal Selection
1.2.2
Digital Section
The digital section contains the microcontroller, USB interface, JTAG header, reset circuitry, and an external interface header (J11). The microcontroller interfaces the energy pulses, E1, E2, and FOUT output by the CS5466 with
the USB connection to the PC. The microcontroller also provides a hardware reset to the CS5466, which is level
shifted to support both +3.3 V and +5 V digital operation. Interface header, J11, is provided to allow the CDB5466U
to be connected to an external energy registration device. The energy output pins E1, E2, FOUT and NEG are routed
to LEDs which provide a simple visual check of the energy output pulses. Jumpers J10, J13, J15 and J16 are
equipped at the factory with jumpers to enable the LEDs.
1.2.2.1
Current Channel Gain
To accommodate different current-sensing elements the current channel incorporates a programmable gain that can
be set to one of four input ranges. Input pins IGAIN1 and IGAIN0 define the four gain selections and corresponding
maximum input signal level. Jumpers J31 and J32 define the state of IGAIN1 and IGAIN0, respectively. Table 4 illustrates the options available. With jumpers J31 = J32 = GND the gain is set to 10x. With jumpers J31 = GND and
J32 = VD+ the gain is set to 50x. With jumpers J31 = VD+ and J32 = GND the gain is set to 100x. With jumpers
J31 = VD+ and J32 = VD+ the gain is set to 150x.
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CDB5466U
Maximum Input Range
IGAIN1
IGAIN0
J31
J32
VD+
IGAIN1 O
GND O
(Default)
VD+
IGAIN0 O
GND O
(Default)
±250mV
10x
±50mV
50x
VD+
IGAIN1
GND
O
O
VD+
IGAIN0
GND
O
O
±25mV
100x
VD+
IGAIN1
GND
O
O
VD+
IGAIN0
GND
O
O
±16.67mV
150x
VD+
IGAIN1
GND
O
O
VD+
IGAIN0
GND
O
O
Table 4. Current Channel PGA Selection
1.2.2.2
High-pass Filter
By removing the offset from either channel, no error component will be generated at DC when computing the active
(real) power. Input pin HPF defines the three options, and J33 defines the state of the HPF pin.
– HPF is enabled in the voltage channel when jumper J33 = GND.
– HPF is enabled in the current channel when pin HPF is connected to pin FOUT.
– High-Pass Filter (HPF) is disabled when jumper J33 = VD+.
HPF
High Pass Filter Option
J33
HPF Option
is in Voltage
Channel
HPF O
HPF O
HPF O
Current
Channel
HPF Option
is in Current
Channel
HPF O
HPF O
HPF O
O
O
VD+
FOUT
GND
Disabled
HPF Option
is Disabled
HPF O
HPF O
HPF O
O
O
VD+
FOUT
GND
Voltage
Channel
O
O
VD+
FOUT
GND
(Default)
Table 5. HPF Option Selection
1.2.2.3
Energy Pulse Outputs
The CS5466 provides three output pins for energy registration. The E1 and E2 pins provide a simple interface from
which energy can be registered. These pins are designed to directly connect to a stepper motor or electromechanical
counter. The E1 and E2 outputs are available on header J11, pins 1 and 3, respectively. The pulse rate on the E1
and E2 pins are in the range of 0 to 4 Hz and all frequency settings are optimized to be used with standard meter
constants. The FOUT pin is designated for system calibration, the pulse rate can be selected to reach a frequency
of 8000 Hz. The FOUT output is available on header J11, pin 5.
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CDB5466U
1.2.2.4
Selecting Frequency of E1 and E2
The pulse rate on E1 and E2 can be set to one of four frequency ranges. Input pins FREQ1 and FREQ0 determine
the maximum frequency on E1 and E2 for sine wave inputs with zero phase shift. The frequency of E2 is equal to
the frequency of E1 with active-low alternating pulses. Table 6 illustrates the options available.
The maximum frequency on the E1 and E2 output pins is determined by the position of the jumpers on J28, J29 and
J30, if the maximum peak differential signal applied to both channels is a sine wave with zero phase shift.
Maximum Frequency for a Sine Wave
Frequency Select
FREQ2
FREQ1
FREQ0
J28
J29
J30
E1 or E2
E1+E2
0.125 Hz
0.25 Hz
64x(E1+E2)
16 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
0.25 Hz
0.5 Hz
32x(E1+E2)
16 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
0.5Hz
1.0 Hz
16x(E1+E2)
16 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
1.0 Hz
2.0 Hz
2048x(E1+E2)
4,096 Hz
0.125 Hz
0.25 Hz
128x(E1+E2)
32 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
0.25 Hz
0.5 Hz
64x(E1+E2)
32 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
0.5 Hz
1.0 Hz
32x(E1+E2)
32 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
1.0 Hz
2.0 Hz
16x(E1+E2)
32 Hz
VD+
FREQ2
GND
O
O
VD+
FREQ1
GND
O
O
VD+
FREQ0
GND
O
O
FOUT
VD+ O
FREQ2 O
GND
(Default)
VD+ O
FREQ1 O
GND
(Default)
VD+ O
FREQ0 O
GND
(Default)
Table 6. Energy Output Frequency
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CDB5466U
1.2.3
Power Supply Section
Table 7 illustrates the power supply connections to the evaluation board. The +5 binding post (J3) supplies the positive analog supply (VA+) for the CS5466 and the +2.5 V reference. The VD+_EXT binding post (J5) supplies the
digital section of the CS5466 (VD+) and level shifters. Jumper J8 allows the VD+ supply to be sourced from the
VD+_EXT binding post (J5), the +5 V binding post (J3), or the regulated +3.3 V supply derived from the microcontroller. The Vu+_EXT (J6) binding post supplies the positive supply for the 8051 processor (8051_REGIN). Jumper
J9 allows the 8051_REGIN supply to be sourced from either the Vu+_EXT binding post (J6), +5 V binding post (J3)
or VD+_EXT binding post (J5).
Power Supplies
Power Post Connections
Analog (VA+) Digital (VD+) 8051 (Vu+)
+5V
GND
VD+EXT VU+EXT
NC
VD+
8051-REGIN
J8
J9
VD+_EXT
+5 O
+3.3 O
O
O
O
VD+
VD+
VD+
Vu+_EXT
+5
VD+
(Default)
NC
+5
+5
+5
+5
O
O
O
O
O
8051
8051
8051
(Default)
+5
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
NC
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
NC
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O
O
O
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
NC
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
+5
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
NC
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
+5
VD+_EXT
+5 O
+3.3 O
O VD+
O VD+
O VD+
Vu+_EXT
+5
VD+
O
O
O 8051
O 8051
O 8051
0
+5
8051
8051
8051
+5
NC
NC
+5
+3.3
+5
+5
0
+3.3
Table 7. Power Supply Connections
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2. SOFTWARE
The evaluation board comes with a USB cable to link the evaluation board to the PC. The evaluation software is
available for download on the Cirrus Logic web site at http://www.cirrus.com/industrialsoftware and is designed to
run under Windows® 2000 or Windows® XP.
2.1
Installation Procedure
The CDB5466U is designed to perform active energy measurement and output energy pulse registration upon powering up. Evaluation software is available to aid in registering energy pulse outputs. To install the software, go to the
Cirrus Logic WEB site at http://www.cirrus.com/industrialsoftware and refer to application note AN278.
2.2
Using the Software
Before launching the evaluation software, check all jumper settings on the CDB5466U evaluation board as described in Section 1, and connect the board to an open USB port on the PC using the provided cable. Once the board
is powered on, the software program can be launched.
2.2.1
Start-Up Window
When the software is launched, the Start-Up window will appear. This window contains information concerning the
software’s title, revision number, copyright date, etc. See Figure 2.
Figure 2. CDB5466U Start-up Window
At the top of the screen is a menu bar which displays user options. The menu bar has three items; Menu, Setup and
Quit. Initially Menu is disabled to prevent conflicts with other serial communications devices. After establishing communication with the CDB5466U evaluation board the Menu item will become available.
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CDB5466U
2.2.1.1
Setup
Setup presents the communication connections available to the CDB5466U Evaluation Board. The CDB5466U has
one connection option available, USB. As depicted in Figure 2, if the USB setup is selected, the evaluation software
will poll the CDB5466U, verifying the serial communication link is ready. At this point USB is checked indicating that
the PC has successfully communicated with the CDB5466U Evaluation Board.
If the evaluation software is unable to establish a communication link with the CDB5466U a message window will
appear, indicating that the initial communication has failed. See Figure 3.
Figure 3. Alert Window
Check to verify that the USB cable is connected properly and the power supply is on and connected properly to the
CDB5466U.
2.2.1.2
Quit
Quit allows the user to exit the evaluation software. Upon selecting Quit, a message window appears and queries if
exiting the evaluation software is desired. See Figure 4.
Figure 4. Quit Window
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CDB5466U
2.2.1.3
Menu
Menu allows one selection option, Pulse Rate Window. The Pulse Rate Window provides a means to register the
energy-to-pulse outputs. See Figure 5.
Figure 5. CDB5466 Evaluation Board
Upon selecting Pulse Rate Window, the CS5466 Pulse Rate Output Window will appear.
2.2.2
CS5466 Pulse Rate Output Window
The Pulse Rate Output Window provides a means to access the E1, E2 and FOUT pin of the CS5466. See Figure 6.
Figure 6. CDB5466U Pulse Rate Output Window
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CDB5466U
In the CS5466 Pulse Rate Output Window, the Pulse Count, Frequency, Average Freq and Standard Deviation are
displayed for the three energy-to-pulse outputs.
Count Span: The Count Span entry allows for a time period to be specified for counting the energy pulses output
by the CS5466. The Count Span is a decimal number having a range of 0.18 < Count Span < 167,772, with units of
seconds.
Periods to Average: The Periods to Average entry allows an average to be performed on the pulses counted during
the specified Count Span. The Periods to Average is an integer with a range of 1 < Periods to Average < 10,000.
Reset DUT: When this button is selected, the evaluation software will request the microcontroller to hardware reset
the CS5466. The CS5466 will perform a reset as discussed in the CS5466 data sheet.
Start/Stop: Initially the Stop button is hidden. When the Start button is selected, the evaluation software will instruct
the microcontroller to start counting the energy-to-pulse outputs from the CS5466. At this time the Start button is
disabled and the Stop button will appear. The evaluation software will then collect the Pulse Count over a duration
of time specified (in seconds) by the Count Span. The counted pulses will then be averaged over the specified Periods to Average entry. The Pulse Count and calculated Frequency, Average Freq and Standard Deviation will be
displayed at the end of the cycle.
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Figure 7. Analog Inputs
3. SCHEMATICS
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Figure 8. CS546x and Socket
CDB5466U
14
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Figure 9. CS5462 and CS5466 Configuration
CDB5466U
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Figure 10. Microcontroller and USB Interface
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Figure 1. Silk Screen
Figure 11. Power Supply
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Figure 1. Topside Layer
4. LAYOUT
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Figure 1. Bottomside Layer
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Contacting Cirrus Logic Support
For all product questions and inquiries contact a Cirrus Logic Sales Representative.
To find one nearest you go to www.cirrus.com
IMPORTANT NOTICE
Cirrus Logic, Inc. and its subsidiaries ("Cirrus") believe that the information contained in this document is accurate and reliable. However, the information is subject
to change without notice and is provided "AS IS" without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant
information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale
supplied at the time of order acknowledgment, including those pertaining to warranty, indemnification, and limitation of liability. No responsibility is assumed by Cirrus
for the use of this information, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third
parties. This document is the property of Cirrus and by furnishing this information, Cirrus grants no license, express or implied under any patents, mask work rights,
copyrights, trademarks, trade secrets or other intellectual property rights. Cirrus owns the copyrights associated with the information contained herein and gives consent for copies to be made of the information only for use within your organization with respect to Cirrus integrated circuits or other products of Cirrus. This consent
does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale.
CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE ("CRITICAL APPLICATIONS"). CIRRUS PRODUCTS ARE NOT DESIGNED, AUTHORIZED OR WARRANTED FOR USE
IN AIRCRAFT SYSTEMS, MILITARY APPLICATIONS, PRODUCTS SURGICALLY IMPLANTED INTO THE BODY, AUTOMOTIVE SAFETY OR SECURITY DEVICES, LIFE SUPPORT PRODUCTS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD
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THESE USES.
Cirrus Logic, Cirrus, and the Cirrus Logic logo designs are trademarks of Cirrus Logic, Inc. All other brand and product names in this document may be trademarks
or service marks of their respective owners.
Windows is a registered trademark of Microsoft Corporation.
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