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2 N D - G E N E R A T I O N P R O SLIC ® GUI U S E R ’ S G U I D E
1. Introduction
The 2nd-Generation ProSLIC® Graphical User Interface (GUI) software uses the USB port or the parallel port of a
PC to communicate with the ProSLIC. Either the USB-capable Voice motherboard (VMB) or an older parallel port
ProSLIC motherboard may be used with the software. The Voice motherboard accesses the ProSLIC's SPI and
PCM ports, while the ProSLIC motherboard only accesses the SPI port. This document applies to Rev 0.98 of the
software. The program runs on Windows 98/NT/2000/XP. Invoking the 2nd-Generation ProSLIC GUI causes the
Voice motherboard to be initialized (if it is connected) and the ProSLIC to be taken out of reset.
2. Installation
To install the 2nd-Generation ProSLIC GUI, run setup.exe. If a previous installation of the software is detected,
running setup.exe uninstalls the old version, and it is necessary to run setup.exe again. When setup installation is
complete, installation instructions for the USB driver for the Voice motherboard are displayed. At this point, connect
the USB cable from the PC to the Voice motherboard. If prompted to install a driver, direct Windows to use the
directory specified in the instructions displayed at the end of the installation in:
C:\Program Files\Silicon Laboratories\VMB Driver\
If you are not prompted to install the USB driver, it is recommended that you uninstall the old driver and install the
driver provided with the software.
2.1. Reinstall USB Driver
To uninstall the USB driver, go to Start->Control Panel, and double-click on “System”. Go to the “Hardware” tab as
shown in Figure 1.
Figure 1. System Properties Screen
Rev. 0.2 5/07
Copyright © 2007 by Silicon Laboratories
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Then, click on “Device Manager”. Expand USB controllers, and you should see “USBXpress Device” as shown in
Figure 2.
Figure 2. Device Manager Screen
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Right-click on this device, and choose "Update Driver…". Decline connecting to Windows Update by choosing "No,
Not this time" when prompted as shown in Figure 3.
Figure 3. Hardware Update Wizard
Click “Next”. Then, choose "Install from a list or specific location (Advanced)" as shown Figure 4.
Figure 4. Installing Software for USBXpress Device
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Click “Next”. Now, choose “Search for the best driver in these locations”, and use the “Browse” button to specify
C:\Program Files\Silicon Laboratories\VMB Drivers as shown in Figure 5.
Figure 5. Search and Installation Options
Click “Next”, and the drivers will be updated as needed.
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3. Launching The Software
The 2nd-Generation ProSLIC GUI may be used with either the older ProSLIC motherboard or the Voice
motherboard; however, by default, the USB interface for the Voice motherboard is selected.
3.1. Voice Motherboard (USB)
First, make sure that the USB cable is connected and that power is applied to the Voice motherboard. Click on the
shortcut in the start menu at Program Files → Silicon Laboratories → 2nd Generation ProSLIC GUI. Select Si324x
or Si3226 and click “OK”. If you receive a message like the one in Figure 6, make sure that the Voice motherboard
driver is installed, the USB cable is connected, and that no other running software is accessing the Voice
motherboard.
Figure 6. USB Error
Sometimes, it may be necessary to unplug the USB cable and reconnect it to the Voice motherboard to reset the
USB device. The Voice motherboard defaults to SPI/PCM communication; however, GCI communication can also
be used. To use GCI, first connect SDITHRU on the ProSLIC to ground, and then select “Connect Motherboard”
and “Connect USB (GCI)”.
3.2. ProSLIC Motherboard (Parallel Port)
Click on the shortcut in the start menu at Program Files → Silicon Laboratories → 2nd Generation ProSLIC GUI.
Ignore any error message pertaining to the USB interface. To enable the parallel port interface, go to the menu bar
at the top, and select “Connect Motherboard”; then, select “Connect LPT”. Make certain that power is applied to the
board. If the parallel port address differs from the default (0x378), select the “Options” menu item; then, select
“Parallel Port Config” to change the port address being used.
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4. ProSLIC Communication
On the top left of the screen, there are several important controls, shown in Figure 7. The “Channel” control selects
the channel with which the software is currently communicating. The value can range from 0 to 31 for a total of 32
channels. The “Broadcast” control enables the broadcast bit in the SPI control byte during register writes, allowing
the user to write to all channels simultaneously. The “RESET” button pulls the ProSLIC's reset pin low when it is
pressed. This button may also be activated using the Escape key.
Figure 7. Screen Top Left
The “Initialize” button determines how many channels are present, reads the device ID of the current channel,
reads the detected PCLK rate, and displays this information on the top right of the screen. Pushing this button also
loads the contents of the initialization file to the ProSLIC. The file is located in the installation directory and contains
the recommended initialization sequence. This file may be edited to change the behavior of the “Initialize” button.
The format of this file and other files used by the software are described later in this document. If the “All Channels”
control is checked, all channels are initialized according to the contents of the initialization file; otherwise, only the
channel currently selected is affected by the “Initialize” button. Select the appropriate BOM option using the
“Linefeed” selector before pressing “Initialize”.
On the bottom left of the screen, there are controls to read and write single registers or RAM locations (see
Figure 8). Select whether you would like to access a register or a RAM location and enter the address to access. If
writing to the ProSLIC, enter data to write in the box next to the “Write” button, and then click either “Write” or
“Read” to execute. Data read back is displayed in the box next to the “Read” button.
Figure 8. Single Reads/Writes
Also shown in Figure 8 is the User Mode control, which is activated by clicking on the green area. If User Mode is
successfully entered by the ProSLIC, the control turns bright green to confirm.
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5. Registers/RAM
When you launch the software, the “Registers/RAM” tab, which displays a table of all the registers in the ProSLIC,
appears on the right side of the screen (see Figure 9). Hold the mouse over the register locations to see the
address of each register, or, alternatively, select “Display Addresses” below the register table to change from
displaying the register names to displaying the register addresses in the table. The “Read All” button executes a
one-shot read of all the registers in the table, whereas the “Continuous Read” button causes the table to be
continuously updated until Continuous Read is turned off. Typing a new value in one of the boxes in the register
table causes a register write to take place.
Figure 9. Registers/RAM
The RAM table on the right side of Figure 9 behaves similarly with its own “Read All” and “Continuous Read”
buttons; however, in this case, only the visible values in the RAM table are updated when Continuous Read is
turned on. The address and name of each RAM location are always displayed. The RAM locations may be sorted
numerically or sorted by function. When the RAM values are sorted by function, the “Go To” control helps navigate
to RAM locations relating to a particular function without scrolling through the table. Certain RAM locations can be
converted to their decimal equivalent by first clicking on the value and then hovering the mouse over the RAM
table. Typing a new value into the “Value” column of the RAM table causes a RAM write to take place. Use the
“Search String” box to search for a RAM location, and navigate through the matches using the “Next” button.
While Continuous Read is active on the register table, the Interrupts Accumulator is updated. The values read from
the IRQ registers are ORed together until the “Clear” button, shown in Figure 10, is pressed.
Figure 10. Interrupts Accumulator
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6. Gauges
The Gauges tab is shown in Figure 11. These controls are used to view the monitor ADC (MADC) value in decimal
units. To activate the gauges, turn on the “Continuous Update” control and select whether you want to scale the
power to full scale or to the value of the power threshold registers using the “Power Scaling” control.
Figure 11. Gauges
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7. Graph
The graph tab is shown in Figure 12. These controls can be used to plot the value of registers or RAM locations
over time. The Y axis is a linear decimal scale, and autoscaling can be turned on or off by right-clicking on the Y
axis. The X axis can be adjusted by entering different values in the “# samples shown” field. This alters the number
of samples displayed on the plot. Enter the locations you wish to read in the “Graph Read Info” box at the top left.
RAM locations can be multiplied by a scaling factor before they are plotted by entering a value other than 1 in the
LSB field. The graph plots data as long as the “Continuous Update” button is active; however, the “Triggered Stop”
controls can be used to stop the data acquisition when a specified rising or falling edge occurs. Choose which edge
to trigger on using the “Trigger” control and specify the threshold using the “Trigger Value” box. The “Hold Samples”
box specifies how many samples before the event are saved. Click “Enable” to enable the trigger, and turn on
“Continuous Update”, if it is not already active. To aid in the detailed examination of plots, two cursors are available.
The cursor controls are on the top left of the graph.
The mean, standard deviation, variance, or RMS value can be calculated for the first address to be read. Select the
calculation to perform using the "Parameter to calculate:" selector; the result is displayed beneath the selector. The
units displayed on the Y axis can be adjusted using the “Y Scale Format” and “Y Scale Precision” controls. The
time between samples on the graph can also be manipulated using the “Time Between Samples” control. The
maximum sample rate possible is achieved using a zero millisecond time between samples and is limited by the
number of devices on the USB bus and the CPU load of the PC running the software.
Figure 12. Graph
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8. Audio (Voice Motherboard Only)
The audio tab is shown in Figure 13. The functionality of this tab is only valid with the Voice motherboard (USB
interface). The Voice motherboard is capable of transmitting and collecting PCM samples. Before any audio
transfers are attempted, the PCM clocks and format must be set up.
In GCI mode, this panel shows the status of the C/I bits and allows the user to change the downstream C/I bits. The
C/I bit indicator updates when the “Run Acquisition” control is turned on.
Figure 13. Audio
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9. PCM Configuration (Voice Motherboard)
Unlike previous ProSLIC motherboards, the configuration of the PCM bus for the Voice motherboard is
accomplished via software. The ProSLIC GUI allows you to configure the PCM clock rate, PCLK source, and
FSYNC source. In addition, the DSP on the Voice motherboard allows PCM data to be passed between the PC and
the ProSLIC. The PCM timeslots used by the DSP are also configurable.
While the ProSLIC's PCM timeslots can be configured to use any bit count for PCM transfers, the Voice
motherboard's DSP can only be configured on 8- or 16-bit boundaries. For example, if you select a TXSLOT of 1 in
8-bit mode, you would need to set the ProSLIC PCMRX registers to 8 (1x8bits) to receive the data. Almost all
features relating to the PCM capability of the Voice motherboard are located on the Audio tab. Table 1 shows the
main configuration parameters for the Voice motherboard PCM.
Select the PCM format in the “DSP PCM” control on the Audio tab and press “Update DSP” to configure the Voice
motherboard's DSP to receive samples of this type. Pressing “Update SLIC” updates the current ProSLIC channel
with the same PCM settings except that the ProSLIC transmit timeslot is equal to the Voice motherboard's receive
timeslot and vice versa. The Voice motherboard now sends/receives audio to/from the current channel.
The DSP on the Voice motherboard has a 1024 word buffer for sending PCM data to the ProSLIC. This buffer loops
continuously and can be loaded using the controls in the “TX” box on the Audio tab. DC, square, sine, and ramp
waveforms are available. Press “Update” to load the buffer.
The units for the amplitude are specified as either codes or volts in the “Graph Controls” box below the audio plot.
“Codes” refers to the raw values coming from the PCM, which could be 8- or 16-bit, while “Volts” displays a scaled
value less than one. When the “Run Acquisition” button is active, data is pulled from a FIFO in the Voice
motherboard's DSP and plotted on the screen. Data can be plotted in the time domain or the frequency domain,
and the data buffer size for the GUI can be adjusted with the “Buffer Size” control. The “Measurement” control
enables or disables the update of values calculated in the “Graph Measurements” display.
Note: In GCI mode, PCLK and FSYNC are generated by the Voice motherboard, and subframes 0 and 1 are used. The data
displayed in the audio graph will come from whichever channel is selected by the “Channel” control.
10. File Input And Output
Figure 14 shows the file input/output controls. The file format described here is the same as the format used for the
initialization file loaded by the “Initialize” button.
Figure 14. File IO
First, select a file name by either entering it manually into the “File Name” box or by clicking on the yellow folder
button. To output the current register and RAM contents of the current channel, click on the “Read” button so that it
now says “Write” and then press “OK”. If an existing file is chosen, a prompt asks if the program can overwrite the
file. Navigate to the file you selected in the first step; it will look similar to Figure 15.
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Table 1. Voice Motherboard PCM Main Configuration Parameters
Parameter
Options
Location
PCM Clock Frequency
All supported by ProSLIC
Audio Tab → PCLK Freq
External PCLK/FSYNC
Enable/Disable
Menu: Options → External PCM Source
External FSYNC
Enable/Disable
Menu: Options → External FSYNC only
DSP Timeslots
8- or 16-bit boundaries
Audio Tab → DSP PCM → TXSLOT/RXSLOT
Figure 15. Example File
When inputing a file, click on the “Write” button to change it back to “Read” and click “OK”. To apply the file to all
channels, the “All Chan” box should be checked. If “All Chan” is enabled, the file is read through once for each
channel. Do not enable broadcast when loading a file. All recently loaded files are selectable using the “Recent
Files” control.
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11. File Format
In the files used to input or output register and RAM values, there are several things to remember.
Lines beginning with the # character are ignored.
Register/RAM addresses are in decimal format while register/RAM values are in hexadecimal format. For
example:
Register 11 = 15
#will write register 11 to 0x15
RAM 600 = 12345678 #will write RAM 600 to 0x12345678
Delays can be inserted with the WAIT command. For example:
WAIT 100
#will wait 100 ms before proceeding
The current channel can be changed using the channel command, but this command should not be used when
the All Chan box is checked since it causes the file to be loaded once for every channel and may lead to
confusing results.
CHANNEL 2
#switch to channel 2
The RESTORE command can be used to go back to whatever channel was selected before any changes to the
current channel were made by CHANNEL commands in the file. For example:
RESTORE
#restore original channel number
User mode can be enabled and disabled using the USER and LOCKUSER commands. For example:
USER
#enable user mode
The patch RAM can be loaded using the PATCH command. For example:
PATCH C:\PATCHFILE.DSP_PROM
#Load Patch
Commands from another file can be executed by using the INCLUDE command. For example:
INCLUDE C:\INPUT2.TXT
Calibration can be performed using the CAL command. This will cause the CAL bit to be set, and the software
will not proceed until the CAL bit clears (or the timeout period expires).
LOCKUSER
#disable user mode
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12. RAM Access Type
In the “Options” menu, there is an item called “16 bit RAM Accesses”. When this is enabled, the lower 13 bits of
each 29-bit RAM location are cleared, and RAM accesses are performed using the 16-bit SPI accesses. This
option is not valid for GCI.
13. Tools Menu
The tools menu contains many useful tools for calculating register and RAM values. Clicking on an item in this
menu brings up a popup with the requested tool, which can subsequently be closed by pressing the Escape key or
pushing the “Close” button.
13.1. Tone Generator
The Tone Generator tool is used to calculate coefficients for the tone generators inside the ProSLIC. Select the
desired amplitude, frequency, and cadence, and then press “Load Values” to load the configuration into the
ProSLIC. The calculated register values are displayed.
13.2. PCM Config
The PCM Config tool can be used to configure the PCM registers of many channels at once. Press “Load” to
update the ProSLIC.
13.3. DC Feed
The DC Feed tool is used to calculate the parameters for the ProSLIC dc feed. It shows a plot of the expected dc
feed curve. Warnings appear if the values entered are unachievable; however, if desired, these warnings can be
disabled by checking “Turn off out of range warnings”. To load the calculated outputs to the ProSLIC, click “Load
Values”.
13.4. Load Patch RAM
The patch RAM load tool can be used to download patch code to the ProSLIC. Select a dsp_prom file by clicking
on the yellow folder icon next to the “Patch Code File” box, and then press “Load Patch” to load the patch RAM.
The entry points table should be filled in automatically when you select a valid patch code file. It is best to load a
patch using an input file during initialization.
13.5. Pulse Metering (Si324x)
The pulse metering tool is used to program the pulse metering registers but also contains a timer for ramping up
and down the pulse metering tone. Configure the pulse metering parameters and then click “Load Values” to
program the ProSLIC. To use the timer function, enter values for “Time On” and “Time Off” and then enable the
timer by turning on the “Run Metering” button. The ramp bit is toggled automatically at the programmed rate.
13.6. Toggle Register State
The toggle register state tool behaves similarly to the pulse metering timer function but is more flexible. Select
which address to toggle and enter values for the on state and off state. Finally, enter the values for “Time On” and
“Time Off” so that the chosen address toggles between the two values when the “Run” button is turned on.
13.7. Battery Switching (Si324x)
The battery switching tool aids in programming the registers related to battery switching. Configure the battery
voltage and GPIO setup, and then click the “Load” button to configure the ProSLIC.
13.8. Ringing
The ringing tool calculates ringing register values as well as ring trip parameters. Enter the ringing cadence,
frequency, amplitude, and offset. Then, enter the ring trip parameters, and click “Load” to write these values to the
ProSLIC.
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13.9. FSK
The FSK tool calculates the FSK generation coefficients for caller ID. Enter the frequencies for mark and space as
well as the amplitude and baud rate. Clicking “Load” will cause the settings to be written to the ProSLIC.
13.10. MADC
The MADC tool displays the monitor ADC values in hexadecimal as well as decimal similar to the “Gauges” tab.
The advantage of the MADC tool is that more of the MADC registers are displayed. Optionally, the values can be
averaged by changing “number of samples to average”.
14. Coefficient Generator
The Coefficient Generator (on the menu bar) can be used to generate the impedance coefficients. The user may
input the desired impedance values using a text file. The output is also provided in a text file. The user may also
enter input values on the screen by choosing the “Use Screen Input with the Input Method” control. The values
specified in the RRC boxes on the screen are then used along with the values listed in Table 2 to calculate the
coefficients. The format of the RRC inputs for both the screen input and the file input mode is selected using the
RRC format control.
Table 2. Values Used with Screen Input
Input
Value
cline
10 nF
cac
100 nF
tx_gain
0 dB
rx_gain
0 dB
tx_spec
See example input file
rx_spec
See example input file
14.1. Coefficient Generator Input File
Once you have installed the ProSLIC GUI, several example input files for the Coefficient Generator are provided.
They are located in the install directory in the folder "File Examples". The input file templates are also accessible
through a shortcut in the start menu. Choose Start → Programs → Silicon Laboratories, and click “Input_Template”.
To use the provided Microsoft® Excel file, first make any changes to the input values, and save the file as a .txt file.
The resulting text file may be used as an input to the Coefficient Generator.
The input files created by the user must be of the same format as the provided example input file. There are three
ways to input the 2-Wire and Balance Impedance:
RRC Model
S Domain
Spectrum (magnitude and phase)
The program chooses whichever comes first in the input file. All of these options are demonstrated in the example
input file. To select an input file, click on the yellow folder icon to the right of the input file text box. The Windows®
file open dialog appears. Alternatively, the full path of the file may be typed into the text box. Selection of the output
file is performed in a similar manner. To view the input or output file selected, push the “View/Edit File” button next
to the appropriate text box. The status indicator at the top left of the screen shows "Ready" until “Calculate
Coefficients” is clicked. It shows "Working…" while the program is running the calculations.
When the calculations are complete, it shows "Ready" again, and the resulting output files are displayed in
Windows® Notepad. The results are also displayed in the output graphs to the right of the screen. The scale of
these graphs can be changed by selecting the text on the axes and changing the minimum and maximum values.
Click on the tabs at the top to view the various graphs. To reload these graphs from a previously-created output file,
select the file in the output file text box, and click “Reload Output Graphs from Output File”. The input graph on the
bottom left shows the values of the desired TX and RX magnitude spectrums.
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14.2. Coefficient Generator Input File Format
Any lines beginning with the "#" character are treated as comments and are ignored. The lines beginning with "$"
are flags for the program. For example, the 2-wire impedance in the RRC format is as follows:
$z_rrc start flag
#2-wire impedance (RRC model) comment
600.000000 values
0.000000
0.000000
$ end flag
Table 3 describes the various input values.
Table 3. Input Values
Input File
Flag
Order of Values in File
Range
Description
b_rrc
R (Ω)
R (Ω)
C (nF)
3 values
Balance impedance (RRC model)
z_rrc
R (Ω)
R (Ω)
C (nF)
3 values
2-wire impedance (RRC model)
b_spec
Frequency (Hz) Magnitude (dB)
Phase (rad)
Any number of points
from 0 to 4 kHz
Balance impedance (spectral)
z_spec
Frequency (Hz) Magnitude (dB)
Phase (rad)
Any number of points
from 0 to 4 kHz
2-wire impedance (spectral)
b_s
The first value, b_s(1), is the coefficient associated with the s9 term in
the numerator polynomial, b_s(10)
is the constant term. b_s(11–20)
are likewise for the denominator
20 values
Balanced impedance (s-domain –
10th-order numerator and 10thorder denominator
z_s
The first value, z_s(1), is the coefficient associated with the s9 term in
the numerator polynomial, z_s(10)
is the constant term. z_s(11–20) are
likewise for the denominator
20 values
2-wire impedance (s-domain –
10th-order numerator and 10thorder denominator
tx_spec
Frequency (Hz) Magnitude (dB)
(0.2–3.4 kHz) 321 points Desired TX magnitude spectrum
spaced 10 Hz
rx_spec
Frequency (Hz) Magnitude (dB)
(0.2–3.4 kHz) 321 points Desired RX magnitude spectrum
spaced 10 Hz
tx_gain
Magnitude (dB)
1 value
Desired TX gain
rx_gain
Magnitude (dB)
1 value
Desired RX gain
cline
C (nF)
1 value
External line capacitor value
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Table 3. Input Values (Continued)
Input File
Flag
Order of Values in File
Range
cac
C (nF)
1 value
rprot
R (Ω)
Description
External ac coupling capacitor
value
External protection resistor value
14.3. Coefficient Generator Output File
The generated output file contains the resulting return losses, TX spectrum, RX spectrum, and coefficients. The
corresponding inputs are at the end of the file. The program also generates a file that is compatible with the file
input capability of the ProSLIC GUI (see Figure 14). The coefficients are listed first in hexadecimal format. Next in
the file is the 2-wire return loss (labeled "rl") specified by 321 points from 200 to 3400 Hz. The 4-wire return loss
("bal") is listed next in the same format. Then, the resulting RX and TX spectrums are listed. The points are
specified as frequency (Hz), magnitude (dB), and phase (rad).
14.4. Example Coefficient Generator Input File
#Example input file for Si324x Coefficient Generator
#Application picks input format that comes first in file
#out of
# 1: b_rrc and z_rrc
# 2: b_spec and z_spec
# 3: b_s and z_s
#This example uses the RRC model format of input
$b_rrc
#balance impedance (RRC model)
600.000000
0.000000
0.000000
$
$z_rrc
#2-wire impedance (RRC model)
600.000000
0.000000
0.000000
$
$cline
#nF
10.00
$
#external line capacitor value
$cac
#nF
100.0
$
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#external AC coupling capacitor value
$rprot
0.000000
$
#external protection resistor value
$tx_spec
#Freq Mag
#desired TX magnitude spectrum (0.2-3.4kHz) 321 points spaced 10Hz
#end points are specified here (the rest are interpolated)
200 0.000000
3400 0.000000
$
$rx_spec
#Freq Mag
#desired RX magnitude spectrum (0.2-3.4kHz) 321 points spaced 10Hz
#end points are specified here (the rest are interpolated)
200 0.000000
3400 0.000000
$
$tx_gain
#tx gain
0.0
$
$rx_gain
#rx gain
0.0
$
14.5. DSL Splitter Applications
Contact Silicon Labs for coefficients to use in DSL applications.
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CONTACT INFORMATION
Silicon Laboratories Inc.
400 West Cesar Chavez
Austin, TX 78701
Tel: 1+(512) 416-8500
Fax: 1+(512) 416-9669
Toll Free: 1+(877) 444-3032
Email: [email protected]
Internet: www.silabs.com
The information in this document is believed to be accurate in all respects at the time of publication but is subject to change without notice.
Silicon Laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences resulting from
the use of information included herein. Additionally, Silicon Laboratories assumes no responsibility for the functioning of undescribed features
or parameters. Silicon Laboratories reserves the right to make changes without further notice. Silicon Laboratories makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Silicon Laboratories assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. Silicon Laboratories products are not designed, intended, or authorized for use in applications intended to
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Silicon Laboratories, Silicon Labs, and ProSLIC are trademarks of Silicon Laboratories Inc.
Other products or brandnames mentioned herein are trademarks or registered trademarks of their respective holders.
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