ASC Breakout Board User Guide
EB92 Version 1.0, July 2015
2
ASC Breakout Board
Introduction
Thank you for choosing the Lattice Semiconductor ASC Breakout Board.
This guide describes how to begin using the L-ASC10 (ASC) Breakout Board, an easy-to-use platform for evaluat-
ing and designing with the ASC programmable hardware management expander. This board is designed for use
with a Lattice FPGA evaluation board such as the Platform Manager 2 evaluation board. The board cannot be used
stand-alone as the ASC works with an FPGA to function as a programmable hardware management controller.
The contents of this user guide include a description of the various portions of the evaluation board, the complete
set of schematics and the bill of material for the ASC Breakout Board. The ASC Breakout Board is also known as
the L-ASC10 Evaluation Board.
Features
The ASC Breakout Board features the following on-board components and circuits:
• L-ASC10 (ASC) Hardware Management Expander
• Two Potentiometers for Voltage Monitor Testing
• One Push-Button Switch as GPIO Input
• One 8-bit DIP Switch for I2C Address Selection
• Nine LEDs for GPIO Output
• Two PNP Transistors for Temperature Monitoring
• Jumpers for Reset and Voltage Configuration
• Header for Connection to FPGA Breakout Board
• Footprints for 4 x DC-DC Converters and Components for Trimming Evaluation
• Footprints for 5 V Hot Swap Circuit and 12 V Hot Swap Circuit
• Footprint for 12 V Input DC-DC Converter
The features are described in more detail in the Board Hardware Features.
3
ASC Breakout Board
ASC Breakout Board Photos
Photographs of the top and bottom of ASC Breakout Board are shown in Figure 1 and Figure 2 below. These pho-
tographs show the board with the Hot Swap and Trim circuits populated (which are not populated in the released
version of the breakout board). See Board Hardware Features for more detail on which circuits are populated on
the breakout board. Component location references are relative to the top of the board with the silk screen text in
the readable orientation (as shown in the photo).
Figure 1. ASC Breakout Board - Top View
4
ASC Breakout Board
Figure 2. ASC Breakout Board - Bottom View
5
ASC Breakout Board
Board Hardware Features
The ASC Breakout Board is provided with a limited set of circuits populated. The circuits populated on the breakout
board are described first. The breakout board also includes connections and footprints for evaluating the trimming
and Hot Swap functions of the ASC. These unpopulated circuits are described in the later part of this section.
L-ASC10 (ASC) Device
The L-ASC10 (Analog Sense and Control - 10 rail) is a Hardware Management (Power, Thermal, and Control
Plane Management) Expander designed to be used with Lattice FPGAs to implement the Hardware Management
Control function in a circuit board. The L-ASC10 (referred to as ASC) enables seamless scaling of power supply
voltage and current monitoring, temperature monitoring, sequence and margin control channels. The ASC includes
dedicated interfaces supporting the exchange of monitor signal status and output control signals with these central-
ized hardware management controllers. Up to eight ASC devices can be used to implement a hardware manage-
ment system.
The list below summarizes the hardware features of the ASC used on the breakout board. These features are also
shown in the block diagram in Figure 3. For detailed information on the operation of each feature, see DS1042, L-
ASC10 Data Sheet.
• Voltage Monitors (VMON) – Nine standard channels and one high voltage channel
• Current Monitors (IMON) – One standard voltage and one high voltage
• Temperature Monitors (TMON) – Two external and one internal
• Trim and Margin Circuits (TRIM) – Four channels
• General Purpose I/O (GPIO) – Nine channels
• High Voltage Outputs (HVOUT) – Four channels
• ASC Interface (ASC-I/F) – Connection to main FPGA
•I
2C Interface – A/D Converter measurement interface
6
ASC Breakout Board
Figure 3. ASC Block Diagram
Voltage Monitoring
There are 10 VMON inputs to the analog section of the device (including the HIMONN_HVMON pin). These are
routed to slide potentiometers, board power supplies (not populated), and the on-board Hot Swap circuits (not pop-
ulated).
Most of the voltage monitors on the breakout board have low value series resistors connected between the on-
board components and the voltage monitors. These series resistors are populated so that the on-board voltage
monitor test points can be driven by an off-board source without damaging the on-board components. These series
resistors are not required for a real-world application board.
All voltages can be read out from the A/D converter using I2C. The VMON signal connections and board compo-
nents are described in Table 1. The schematic sheet location for the given components and signals are also listed
(see the Appendix A. Schematics section).
Table 1. Voltage Monitor Components and Signals
Component / Signals Ref. Des. Schematic
Sheet Description
Components Populated on Breakout Board
Slider Potentiometers
(POT1 and POT2)
R50, R52 5 1 kΩ slider pot: provides a variable Voltage from zero
to 3.3 V. Connected to VMON7 and VMON8 of U1
with a 1k series resistor.
Series Resistors R51, R53 5 1 kΩ resistor allows the user to safely drive VMON7
and VMON8 test points with an off-board Voltage
source.
Series Resistors R51, R612 270 Ωresistor allows the user to safely drive VMON5
and VMON6 test points with an off-board Voltage
source.
Output Control
Block
ASC
Interface
(ASC-I/F)
Non -
Volatile
Fault Log
Trim & Margin
Control
ADC
ADC
MOSFET &
Digital I/O Drive
Current
Sense
Voltage
Sense
Temperature
Sense
I
2
C
Interface
A
D
C
A
D
C
7
ASC Breakout Board
Components Not Populated on Breakout Board
Series Resistors R231, R3213 270 Ω resistor allows the user to safely drive VMON1
and VMON2 test points with an off-board voltage
source. (Only needed when DCDC1 and DCDC2 are
populated.)
Ground Sense Resistors R241, R3313 100 Ωresistor allows the user to safely drive the
VMON1_GS and VMON2_GS test points with an off-
board voltage source (such as remote load sensing)
without adding or removing components. (Only
needed when DCDC1 and DCDC2 are populated.)
Series Resistors R401, R4814 270 Ωresistor allows the user to safely drive VMON3
and VMON4 test points with an off-board voltage
source. (Only needed when DCDC3 and DCDC4 are
populated.)
Ground Sense Resistors R411, R4914 100 Ωresistor allows the user to safely drive the
VMON3_GS and VMON4_GS test points with an off-
board voltage source (such as remote load sensing)
without adding or removing components. (Only
needed when DCDC3 and DCDC4 are populated.)
Signals
VMON1 / GS_VMON1 2, 3 Connected to DCDC1 output – 5 V – via R23 series
resistor. Also connected to J4 terminal. See the
Closed Loop Trimming (Not Populated) section for
more details.
VMON2 / GS_VMON2 2, 3 Connected to DCDC2 output – 3.3 V – via R32 series
resistor. Also connected to J5 terminal. See the
Closed Loop Trimming (Not Populated) section for
more details.
VMON3 / GS_VMON3 2, 4 Connected to DCDC3 output – 2.5 V – via R40 series
resistor. Also connected to J4 terminal. See the
Closed Loop Trimming (Not Populated) section for
more details.
VMON4 / GS_VMON4 2, 4 Connected to DCDC4 output – 1.2 V – via R48 series
resistor. Also connected to J4 terminal. See the
Closed Loop Trimming (Not Populated) section for
more details.
VMON5 2, (6), 9 5 V switched input supply to 5 V Hot Swap circuit via
R5 series resistor. Connected to SW1 in Board Power
circuit. See the 5 V Hot Swap (Not Populated) section
for more details.
VMON6 2, (6) 5 V rail supply from either main FPGA board or Hot
Swap output via R6 series resistor. See the 5 V Hot
Swap (Not Populated) section for more details.
VMON7 2, 5 Potentiometer 1 (R50) via R51 series resistor
VMON8 2, 5 Potentiometer 2 (R52) via R53 series resistor
VMON9 2, (7), 9 12 V switched input supply to 12 V Hot Swap circuit
via R65 (part of resistor divider). Connected to SW1
in Board Power circuit. See the 12 V Hot Swap (Not
Populated) section for more details.
HVMON (HIMONN_HVMON) 2, 7 12 V rail supply from either main FPGA board or Hot
Swap output. See the 12 V Hot Swap (Not Populated)
section for more details.
1. Not required for customer designs; this is only needed to support demonstrations on the breakout board.
Component / Signals Ref. Des. Schematic
Sheet Description
8
ASC Breakout Board
The two potentiometers (R50 and R52) are tied to VMON7 and VMON8 these can be used to simulate a fault or trip
a comparator (see Figure 4). The slide potentiometers provide a voltage in the range of 0 V to 3.3 V depending on
their position. R51 and R53 are 1 kΩ series resistors which allow for the connection of an off-board source directly
to the VMON7 and VMON8 test points. The voltage on either potentiometer can be read out from the A/D converter
using the I2C port.
Figure 4. Voltage Monitor Potentiometer Circuits
Temperature Monitoring
The board has PNP transistors mounted in the two corners opposite the main D-SUB connector. The PNP transis-
tors are connected in the beta-compensated PNP temperature monitor configuration (preferred configuration for
temperature monitors), as shown in Figure 5.
Provided the temperature monitors are enabled in the design, the temperature of each sensor can be read out
using I2C. The sensors can also be used to simulate over or under-temperature faults.
Figure 5. Temperature Monitor Circuits
The temperature sensors have 150 pF filter capacitors (C3 and C4) connected across the differential signals to
improve noise-immunity that are located close to the ASC device, as shown in Figure 6.
VMON7
VMON8
+3.3V
+3.3V
POT1 Sheet [2]
POT2 Sheet [2]
+3.3V
R51
1k
R50
1k
1
3
2
R53
1k
R52
1k
1
3
2
Temperature Sensor 1
Temperature Sensor 2
TEMP_SENSE1P
TEMP_SENSE1N
TEMP_SENSE2P
TEMP_SENSE2N
Q4
2N3906
Q3
2N3906
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ASC Breakout Board
Figure 6. Temperature Monitor Connections
The temperature monitor components and signals are summarized in Table 2 below.
Table 2. Temperature Monitor Components and Signals
LED Outputs
The ASC Breakout Board has 9 LEDs tied to the ASC open-drain outputs. The LEDs are pulled up to 3.3 V and are
lit when GPIO1-GPIO10 are driven to a logic low (GPIO7 is not bonded out of the ASC). The LED circuit is shown
in Figure 7 below (taken from Sheet 8 of the schematic).
Figure 7. ASC GPIO LEDs
Push Button
The breakout board has one push-button (SW2), shown in Figure 8 (taken from Sheet 5 of the schematic). This sig-
nal is routed to GPIO10 of the ASC. This GPIO must be configured as an input in Platform Designer in order to use
the push-button. When the button is pressed, GPIO10 is set to 0. When the button is released, GPIO10 is pulled to
1 by R82 (see the LED outputs section). The input signal can be used in the logic design of the main board FPGA.
GPIO10 is shared with LED10, pressing the push-button (SW2) will cause LED10 to illuminate.
Component / Signals Ref. Des. Schematic
Sheet Description
Components Populated on Breakout Board
Temperature Sensor Q3, Q4 5 2N3906 PNP Transistor connected in Beta-Compen-
sated PNP configuration.
Series Resistors C3, C4 2 150 pF input filter capacitors for temperature monitor-
ing signals to reject noise.
Signals
TEMP_SENSE1P /
TEMP_SENSE1N
2, 5 Input from temperature sensor to TMON1 (tempera-
ture monitor input) of L-ASC10
TEMP_SENSE2P /
TEMP_SENSE2N
2, 5 Input from temperature sensor to TMON2 (tempera-
ture monitor input) of L-ASC10
TEMP_SENSE1P
TEMP_SENSE1N
TEMP_SENSE2P
TEMP_SENSE2N
C3
150pF
C4
150pF
TMON1P
21
TMON1N
22
TMON2P
23
TMON2N
24
LED2 LED3 LED4 LED5 LED6 LED8LED9 LED10
LED1
LED[1:10]
+3.3V
D1
Red
RN1A
2.2k
10
1
RN2B
2.2k
2
RN1C
2.2k
3
D4
Red
R82
2.2k
RN1G
2.2k
8
RN1F
2.2k
7
RN1E
2.2k
5
6
RN1H
2.2k
9
D2
Red
D6
Red
RN2A
2.2k
10
1
RN2D
2.2k
4
D7
Red
RN1B
2.2k
2
RN2E
2.2k
5
6
RN2F
2.2k
7
RN2C
2.2k
3
D8
Red
R81
2.2k
RN1D
2.2k
4
D3
Red
D5
Red
RN2H
2.2k
9
RN2G
2.2k
8
D9
Red
10
ASC Breakout Board
Figure 8. Push-Button Circuit
I2C Address Selection DIP Switch
The ASC Breakout Board provides an 8-position DIP switch for I2C address selection of the ASC device. The switch
combines with a set of on-board resistors (R9 – R15) to connect to the I2C_ADDR pin of the device (shown in
Figure 9, taken from Sheet 2 of the schematic). Each switch corresponds to a different resistor setting and address
selection (see the ASC Datasheet for more details). The ASC device only checks the resistor setting at power-on-
reset, updating the switches while the board is powered will have no effect. Only one switch should be closed at a
time.
Figure 9. I2C Address Selection DIP Switch
Reset Configuration Jumper
The ASC on the breakout board can be configured as a Mandatory ASC or Optional ASC. This setting is configured
in the Platform Designer software and described in the System Connections section of the ASC datasheet. The
position of jumper J12 (shown in Figure 10, from Sheet 2 of the schematic) should match the setting in the soft-
ware. This jumper routes the ASC RESETb signal to either the Mandatory Reset signal or to the Optional Reset
signal on the ASC Interface Connector.
Figure 10. Reset Configuration Jumper
LED10
SW2
GPIO10
14
23
ASC I2C Address Select
1
3
2
4
5
7
6
0
I2C_ADDR
+3.3V
SW3E
512
SW3D
413
R9 1K
SW3F
611
SW3H
89
SW3G
710
R10 18.0K
R11 14.0K
R12 10.0K
SW3A
116
R13 7.00K
SW3C
314
R14 4.40K
SW3B
215
R15 2.20K
Mandatory ASC Jumper 2 to 3
Optional ASC Jumper 1 to 2
ASC_RESET
MANDATORY_RESET
ASC_RESETbJ12
HEADER 3
1
2
3
11
ASC Breakout Board
ASC Interface Connector
The ASC Interface Connector (shown in Figure 11 from Schematic Sheet 2) is used to connect the ASC Breakout
Board to the main FPGA Board. The connector has been designed to pair with other available Lattice Evaluation
Boards, including the Platform Manager 2 Evaluation Board (see the related literature section for more details).
The connector includes all the mandatory signals for connecting the ASC device to the hardware management
controller as described in the system connections section of the ASC datasheet. This includes the ASC-Interface
Signals, the I2C signals, and the Clock and Reset signals. The connector also includes a set of power rails as
described in Table 3. Additionally, the connector provides the 5 V and 12 V Hot Swap signals.
Figure 11. ASC Interface Connector
Table 3. ASC Interface Connector Pin Description
Pin # Signal Name Description
1 GND Shared ground signal with main FPGA Board
2 ASC_WDAT ASC-Interface Signal – must be connected to FPGA PIO and assigned
in Diamond
3 ASC_RDAT ASC-Interface Signal – must be connected to FPGA PIO and assigned
in Diamond
4 ASC_WRCLK ASC-Interface Signal – must be connected to FPGA PIO and assigned
in Diamond
5 MANDATORY_RESET RESETb signal if ASC device is declared as mandatory in Platform
Designer. Must match J12 setting (Reset Configuration). Must be con-
nected to FPGA PIO and assigned in Diamond.
6 GND Shared ground signal with main FPGA Board
7 I2C_WRITE_EN Connected to GPIO1 through R4. Used with optional ASC Write Protect
feature. Connect to FPGA PIO and assign in Diamond if this feature is
used.
8 ASC_CLK 8-MHz Clock Output by ASC0 in ASC hardware management controller
systems. This signal is NC for all non-ASC0 ASC devices. ASC0
devices should connect to FPGA PCLK input and assign to ASCCLK
signal in Diamond
ASC Interface Connector
ASC_WDAT
ASC_RDAT
ASC_WRCLK
MANDATORY_RESET
ASC_RESET
I2C_WRITE_EN
+5V_HS
+12V_HS
I2C_SCL
I2C_SDA
5V_OC_SENSE
12V_OC_SENSE
LED2
LED3
ASC_CLK
+3.3V
ASC_12V_OC_SHUTDOWN
+5V_HS
+12V_HS
+3.3V
+11.3V
ASC_5V_OC_SHUTDOWN
J10
CONN DSUB 25-P
1
14
2
15
3
16
4
17
5
18
6
19
7
20
8
21
9
22
10
23
11
24
12
25
13
R7 0
R80
12
ASC Breakout Board
9 +3.3V ASC Supply Voltage. Provided by FPGA board or 12 V power supply
(power supply not populated on Breakout Board).
10 +11.3V Voltage rail generated from diode OR of +12V_SW and +5_SW input
supplies. FPGA main board may use as input to 12 V DC-DC convert-
ers.
11 +12V_HS 12 V supply rail. Output from either 12 V Hot Swap circuit or main FPGA
board. This rail is the input for DCDC1 and DCDC2.
12 +5V_HS 5 V supply rail. Output from either 5 V Hot Swap circuit or main FPGA
board. This rail is the input for DCDC3 and DCDC4.
13 GND Shared ground signal with main FPGA Board
14 ASC_12V_OC_SHUTDOWN Output from main FPGA board, connected to fast shutoff transistor
(Q12) of 12 V Hot Swap circuit. Assign to FPGA PIO in Platform
Designer and Diamond when using 12 V Hot Swap.
15 12V_OC_SENSE Output from ASC device (connected to GPIO3 through R8). Used as
fast shutdown alarm to main FPGA board. Assign to FPGA PIO in Plat-
form Designer and Diamond when using 12 V hot swap.
16 GND Shared ground signal with main FPGA Board
17 ASC_RESET RESETb signal if ASC device is declared as optional in Platform
Designer. Must match J12 setting (Reset Configuration). Must be con-
nected to FPGA PIO and assigned in Diamond.
18 I2C_SCL I2C Clock Signal. Should be connected to FPGA SCL pin. Main FPGA
board should include pull-up resistors. Used for programming the ASC
device.
19 I2C_SDA I2C Data Signal. Should be connected to FPGA SDA pin. Main FPGA
board should include pull-up resistors. Used for programming the ASC
device.
20 ASC_5V_OC_SHUTDOWN Output from main FPGA board, connected to fast shutoff transistor (Q7)
of 5 V Hot Swap circuit. Assign to FPGA PIO in Platform Designer and
Diamond when using 5 V Hot Swap.
21 5V_OC_SENSE Output from ASC device (connected to GPIO2 through R7). Used as
fast shutdown alarm to main FPGA board. Assign to FPGA PIO in Plat-
form Designer and Diamond when using 5 V Hot Swap.
22 GND Shared ground signal with main FPGA Board
23 +12V_HS 12 V supply rail. Output from either 12 V Hot Swap circuit or main FPGA
board. This rail is the input for DCDC1 and DCDC2.
24 +5V_HS 5 V supply rail. Output from either 5 V Hot Swap circuit or main FPGA
board. This rail is the input for DCDC3 and DCDC4.
25 +5V_HS 5 V supply rail. Output from either 5 V Hot Swap circuit or main FPGA
board. This rail is the input for DCDC3 and DCDC4.
Pin # Signal Name Description
13
ASC Breakout Board
Closed Loop Trimming (Not Populated)
The ASC provides four Closed Loop Trim (CLT) cells which are used to accurately trim and margin power supplies.
The ASC Breakout Board provides four DC-DC converter and trimming circuit footprints on the breakout board.
Table 4 lists the components and signal associated with CLT operation on the ASC Breakout Board.
Table 4. Closed Loop Trim Components & Signals
Component / Signals Ref. Des. Schematic-
Sheet Description
Components Not Populated on Breakout Board
DC-DC Converter DCDC1_A /
DCDC1_B
3 Dual-footprint +12 V input adjustable output power
supply. Trim circuit shown in schematic for DCDC1_A
(NQR002A0X4Z) at 5 V output.
DC-DC Converter DCDC2_A /
DCDC2_B
3 Dual-footprint +12 V input adjustable output power
supply. Trim circuit shown in schematic for DCDC2_A
(NQR002A0X4Z) at 3.3 V output.
DC-DC Converter DCDC3_A /
DCDC3_B
4 Dual-footprint +5 V input adjustable output power
supply. Trim circuit shown in schematic for DCDC3_A
(NQR002A0X4Z) at 2.5 V output.
DC-DC Converter DCDC4_A /
DCDC4_B
4 Dual-footprint +5 V input adjustable output power
supply. Trim circuit shown in schematic for DCDC4_A
(NQR002A0X4Z) at 1.2 V output.
N-Channel MOSFET – SOT-23 Q1, Q2 3 FDV301N N-Channel MOSFET. Inverts the DC-DC
enable signal from ASC GPIO8 / GPIO9 and shifts
the level up to +12 V.
Green Indicator LED D19, D20, D21,
D22
3, 4 LED indicates output of DC-DC is active.
LED Bias Resistor R86, R88, R90,
R92
3, 4 470 Ω resistor limits the LED current.
NPN Transistor – SOT-23 Q13, Q14, Q15,
Q16
3, 4 2N3904 NPN Transistor drives LED on when DC-DC
output is active.
NPN Bias Resistor R85, R87, R89,
R91
3, 4 4.7 kΩ resistor limits the base current of NPN transis-
tor.
Tantalum Cap C5, C7, C9, C11 3, 4 6.8 µF, 20 V capacitor DC-DC input filter.
Tantalum Cap C6, C8, C10,
C12
3, 4 10 µF, 6.8 V capacitor DC-DC output filter.
DC-DC Output Load Resistor R22,R31, R39,
R47
3, 4 1k, 680, 470 and 330 Ω resistors pull DC-DC outputs
down to zero when disabled.
DCDC1 Trim Resistors R17 – R21 3 Resistor values based on Platform Designer Trim Cal-
culator for DCDC1_A at 5 V.
DCDC2 Trim Resistors R26 – R30 3 Resistor values based on Platform Designer Trim Cal-
culator for DCDC2_A at 3.3 V.
DCDC3 Trim Resistors R34 – R38 4 Resistor values based on Platform Designer Trim Cal-
culator for DCDC3_A at 2.5 V.
DCDC4 Trim Resistors R42 – R46 4 Resistor values based on Platform Designer Trim Cal-
culator for DCDC4_A at 1.2 V.
Phoenix 4-Terminal Connector
DCDC1-4
J4, J5, J7, J9 3, 4 Wire to board connectors to apply off-board loads to
DC-DC with remote sensing.
Signals
LED8 2, 3 DCDC1 control signal from GPIO8. Safe state is high.
Inverted via Q1.
LED9 2, 3 DCDC2 control signal from GPIO9. Safe state is high.
Inverted via Q1.
LED4 2, 4 DCDC3 control signal from GPIO4. Safe state is low.
14
ASC Breakout Board
Overview of Trim and Margin
The board provides footprints for four DC-DC modules. Since all four are similarly designed and laid out, this sec-
tion will provide an overview of the DC-DC circuit rather than provide a separate section for each DC-DC. Foot-
prints are provided for both 5-pin SIP modules and DOSA power converters. The circuits shown in the schematic
appendix support the NQR002A0X4 SIP from GE Industrial and the OKY-T/3-D12 DOSA converter from Murata.
None of the components associated with the DC-DC operation (shown in Table 4) are populated on the breakout
board.
The ASC Breakout board provides footprints and circuit connections for five trimming resistors for each DC-DC.
These five resistors are shared by both the SIP and DOSA footprints because only one supply can be populated at
a time. The resistors are organized in an “H” pattern both in the schematic and on the board layout. The resistors
are named in the schematic to match the names used in the Platform Designer Trim-view calculator. The names
are listed and described in Table 5 below. Typically only three resistors are suggested by the calculator; a pull-up, a
pull-down, and a series resistor. The exact population of the “H” pattern depends on many factors that the calcula-
tor takes into account such as type of DC-DC, output voltage, and range of trim. The ASC Breakout board provides
pads and connections to support any result from the Trim Calculator. However, with certain supplies and option set-
tings, the calculator can produce a result that only uses two resistors: a pull-down and series resistor. The DC-DCs
on the ASC Breakout board are populated with the two resistor solution. A key requirement for the calculator to pro-
duce a two-resistor solution is the Bi-Polar Zero (BPZ) voltage of the Trim Cell has to match the DC-DC internal ref-
erence voltage. Otherwise the calculator will add a pull-up or pull-down resistor in attempt to offset the imbalance
between the BPZ voltage setting and DC-DC reference voltage. The values shown in the schematic have been cal-
culated for the NQR002A0X4 SIP from GE Industrial. For more information on the Trim interface and Calculator
please see AN6074, Interfacing the Trim Output of Power Manager II Devices to DC-DC Converters and the Plat-
form Designer 3.1 User Guide.
Table 5. Trim Resistor "H-Network" Names.
In order for the CLT circuits within the ASC to operate properly the output of the supply needs to be monitored by
the correct VMON input. The ASC Breakout board illustrates the correct connections by using TRIM1 with VMON1
for DCDC1, TRIM2 with VMON2 for DCDC2, all the way to TRIM4 with VMON4 for DCDC4. As discussed in the
Voltage Monitor Operation section, the DC-DC outputs are connected to the VMON inputs using a series resistor
with a value of 270 Ω. The series resistor is not required in customer designs; its only function on the breakout
board is to isolate the DC-DC outputs from the VMON test point. The VMON series resistor allows another voltage
LED5 2, 4 DCDC4 control signal from GPIO5. Safe state is low.
OUT_DCDC1 2, 3 DCDC1 Output connected to VMON1 via R23.
OUT_DCDC2 2, 3 DCDC2 Output connected to VMON2 via R32.
OUT_DCDC3 2, 4 DCDC3 Output connected to VMON3 via R40.
OUT_DCDC4 2, 4 DCDC4 Output connected to VMON4 via R48.
TRIM_DCDC1 2, 3 DCDC1 Trim signal from TRIM1.
TRIM_DCDC2 2, 3 DCDC2 Trim signal from TRIM2.
TRIM_DCDC3 2, 4 DCDC3 Trim signal from TRIM3.
TRIM_DCDC4 2, 4 DCDC4 Trim signal from TRIM4.
Schematic Name Calculator Name Description
RpupS RpupSupply Pull Up Resistor at DC-DC Supply Trim input
RpdnS RpdnSupply Pull Down Resistor at DC-DC Supply Trim input
Rs Rseries Series Resistor between Trim DAC output and DC-DC Supply Trim input
RpupD RpupDAC Pull Up Resistor at Trim DAC output
RpdnD RpupDAC Pull Down Resistor at Trim DAC output
Component / Signals Ref. Des. Schematic-
Sheet Description
15
ASC Breakout Board
source to be applied to the VMON test point directly. If the voltage source is fairly weak, the VMON series resistor
can be removed.
Each of the DC-DC supplies has a load resistor connected to the output. The load resistor is not required in cus-
tomer designs as the supply is typically connected to a real load. The load resistor is only used on the breakout
board to prevent the output of the supply from “creeping up” when the supply is disabled. Without the load resistor
some disabled supplies may output around 1 Volt that can be read by either the VMON or a Digital Volt Meter
(DVM). The load resistors are sized based on the target DC-DC supply output voltage; lower values for lower volt-
ages and higher values for higher voltages. In all cases they are 1/10 watt packages so there is minimal heat gen-
erated.
DCDC1 – Enable and Trim
This section discusses the specific circuits that support DCDC1. In Figure 12 the control signal LED8, which comes
from GPIO8, is inverted and level shifted by a small signal N-channel MOSFET (Q1 FDV301N). For +12 V supplies
a buffer or inverter is needed because the ASC GPIOs can only be pulled up to +5.5 V. All GPIOs of the ASC have
a “safe state” which defines the behavior independent of configuration during Power-On-Reset (POR) or during
programming; the safe sate of GPIO8 is high. Both the DOSA and SIP supplies are enabled when the On-Off pin is
high (positive enable logic). Since the enable signal is inverted by Q1, the supplies will be off during “safe state”. A
10 kΩ pull-up resistor (R16) to 12 V is used to insure a full logic swing at the enable input of the supplies. (Note that
DCDC3 and DCDC4 do not require the MOSFET circuit, this is because there input supply is +5 V. See Table 6 for
more details).
Figure 12. DCDC1 Trim and Control Circuit
The control signal LED8 is also used to turn on a red LED (D7) when it is low and pulled up to +3.3 V by a 2.2 kΩ
resistor (RN2G – Sheet 8). Depending on the enable logic (positive or negative) of the installed supply, the illumina-
tion of LED D7 may not indicate that DCDC1 is enabled. (When the DC-DC converters from the schematic are
used, DCDC1 and DCDC2 will be enabled when their control LED is illuminated. DCDC3 and DCDC4 will not be
enabled when their control LED is illuminated. This is due to the inverting MOSFET used with DCDC1 and
DCDC2). A separate green LED (D49) is used to indicate when the supply is enabled. An NPN transistor (Q15) is
used to turn the green LED on when the supply has enough voltage to bias the emitter-base junction (slightly more
than 0.7 V).
Supply filtering is provided by a 6.8 µF capacitor (C5) on the input and a 10 µF capacitor on the output (C6). These
are located close to the DC-DC footprints to ensure their effectiveness. Note that these values may not be optimal
for all supplies and loading conditions, specific filtering requirements should be followed from the DC-DC data
sheet.
5V @ 3A
GPIO8
TRIM1
VMON1
5V @ 2A
SIP
OUT_DCDC1
+12V_HS
+3.3V
LED8
Sheet [2,8]
TRIM_DCDC1
Sheet [2]
VMON1Sheet [2]
GS_VMON1 Sheet [2]
+12V_HS
Sheet [2,7]
+3.3V
Sheet [2,4,5,6,7,8,9,10]
J4
DCDC1
A
B
C
D
R22
1K
R23
270
R90
470
NQR002A0X4Z
DCDC1_A
DI
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
C6
10uF
6.8V
R24
100
D21
Green
SM_LED_0603
Q1
FDV301N
R18
2.74k
RpdnS
R21
open
RpdnD
OKY-T/3-D12P-C
DCDC1_B
DNI
GND
3
Vin
2
On-Off Control
1Trim 4
Vout5
R89
4.7k
R16
10K
R20
open
RpupD
C5
6.8uF
20V
R17
open
RpupS
R19
11.0k
Rs
Q15
2N3904
16
ASC Breakout Board
Table 6 shows a summary of the input voltage, output voltage, and control signal behavior for each of the four DC-
DC converters. The +12V_HS and +5V_HS rails which are used to power the DC-DC converters can be provided
by either the Hot Swap circuits or the ASC Interface Board connector. See the connector section for more details.
Table 6. Summary of DCDC Trim Circuits
Board Power Supplies (Not Populated)
The breakout board is supplied by the +3.3 V rail from the ASC Interface connector. The breakout board also pro-
vides the footprint for the power supply circuit shown in Figure 13. Table 7 lists the power supply components on
the ASC Breakout Board.
Table 7. Power Supply Components
The terminal connector J1 connects the +5 V supply to the SW1 power switch. Either the J2 power supply jack or J3
terminal connect the +12 V supply to SW1. Switching SW1 to the on position will connect the terminals to the
+12V_SW supply rail and the +5V_SW supply rail. The +12V_SW supply rail is connected to the D17 TRANZORB to
protect the board from voltage transients. These voltage rails are the input supplies to the 12 V Hot Swap and 5 V Hot
Swap circuits.
DC-DC Vin Vout VMON /
Trim Channel
GPIO Enable
Control
ON Logic
Level RpdnS Rseries
1 +12V_HS 5 V VMON1/TRIM1 GPIO8 0 2.74 kΩ11.0 kΩ
2 +12V_HS 3.3 V VMON2/TRIM2 GPIO9 0 4.42 kΩ16.0 kΩ
3 +5V_HS 2.5 V VMON3/TRIM3 GPIO4 1 6.34 kΩ22.0 kΩ
4 +5V_HS 1.2 V VMON4/TRIM4 GPIO5 1 20.0 kΩ39.0 kΩ
Component Ref. Des.
Schematic
Sheet Description
Components Not Populated on Breakout Board
DC-DC Converter DCDC5 9 SIP +12 V input power supply (NQR002A0X4Z)
trimmed for 3.3 V output. Provides board power sup-
ply from +12 V or +5 V rails.
Power Jack J2 9 +12 V AC Adapter connector.
Phoenix 2-Terminal Connector J1, J3 9 Input terminal for +5 V supply voltage (J1) and +12 V
supply voltage (J3)
Tranzorb TVS Diode D17 9 Transient voltage suppressor diode – protects +12 V
input from external voltage.
Schottky Diode D16, D18 9 Schottky diodes for diode ORing for +11.3 V rail
Tantalum Capacitor C29 9 22 µF, 25 V capacitor +12 V DC-DC input filter.
Ceramic Bypass Capacitors C31, C32 9 100 nF 25 V capacitor +12 V DC-DC input and output
filter.
Tantalum Capacitor C30 9 22 µF, 25 V capacitor +12 V DC-DC output filter.
Trim Resistor R96 9 4.53 kΩ trim resistor, sets DCDC5 output voltage at
+3.3 V
2-pin Header J14 9 Selects +3.3 V sources – populating with jumper
sources +3.3 V from +11.3 V rail, unpopulated
sources +3.3 V from ASC Interface Board connector
17
ASC Breakout Board
Figure 13. Board Power Supply Circuit
The +12 V connects through schottky diode D16 to the +11.3 V rail, while the +5 V connects through schottky
diode D18 to the +11.3 V rail. Through this configuration, the +11.3 V rail will be sourced by either the +12V_SW
rail (if present) or the +5V_SW rail (if present and +12V_SW rail not present). The +11.3 V rail is connected to the
ASC Interface connector. This rail may be used as an input to a 12 V DC-DC converter on the main FPGA board.
The +11.3 V rail is also used as the input voltage to DCDC5. DCDC5 steps down the +11.3 V input to a +3.3 V out-
put voltage. The +11.3 V is buffered and filtered by C29 and C31. The +3.3 V output is buffered and filtered by C30
and C32. The +3.3 V output voltage is set by the 4.53 kΩ resistor (R96) connected to the DCDC5 Trim pin.
The header J14 is used to connect the DCDC5 output to the +3.3 V rail using a 2-pin jumper. Placing a jumper on
J14 will supply the ASC Breakout Board +3.3 V from DCDC5. It will also provide +3.3 V to the ASC Interface Con-
nector – this will power the FPGA main board from only the +12V_SW input on the ASC Breakout Board. No other
input supply is required.
5 V Hot Swap (Not Populated)
The ASC Breakout Board provides a set of footprints and connections for implementing a 5 V Hot Swap circuit
using the ASC’s built in hardware. Table 8 lists the components and signals associated with 5 V Hot Swap opera-
tion on the ASC Breakout Board.
Table 8. 5 V Hot Swap Components and Signals
Component / Signals Ref. Des. Schematic
Sheet Description
Components Not Populated on Breakout Board
Current sense resistor R60265 mΩ 2 W resistor for supply side current monitoring with
IMON1 input of ASC
IMON1 Isolation Resistor R582, R5926 Zero Ω resistors – support population option for standard
MOSFET versus MOSFET with Sense output
MOSFET Switch Q626 N-Channel MOSFET load-side Hot Swap switch supplies
power to +5V_HS and load capacitor C13.
Gate Drive Resistor R6126 2.2 kΩ resistor, located close to MOSFET Q6, limits parasitic
oscillations at the gate of Q6. Works with C22 to slow switching
at Q6, limiting current ripple during hysteretic switching.
Gate-Source Capacitor C2226 100 nF capacitor, works with R61 to slow switching at Q6, lim-
iting current ripple during hysteretic switching.
Populate jumper to provide
3.3V power from ASC Eval
Board
3.3V
1A
12V to 4.8V input range
+11.3V
+3.3V
+12V
+5V
+11.3V
+11.3V
+3.3VSheet [2,3,4,5,6,7,8,10]
+5V_SWSheet [2,6,10]
+12V_SWSheet [7,10]
+11.3VSheet [2]
J14
HEADER 2
1
2
C31
100nF
25V
SW1
SW DPDT
2
3
5
6
1
4
J1
2 Position Terminal Block
A
B
J2
PWR JACK
3
2
1
J3
2 Position Terminal Block
A
B
R96
4.53K
C30
22uF
25V
D17
TRANZORB
C32
100nF
C29
22uF
25V
NQR002A0X4Z
DCDC5
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
D16
NSR0530P2T5G
D18
NSR0530P2T5G
18
ASC Breakout Board
The 5 V Hot Swap circuit is designed to support two separate implementations. The Standard MOSFET implemen-
tation uses a standard power MOSFET (Q6) and a 5 mΩ sense resistor (R60). The MOSFET with Sense output
implementation uses a power MOSFET with current sense output (Q5) and a 3.30 Ω sense resistor. The Standard
MOSFET implementation is a Load-based Hot Swap implementation with the MOSFET connected between the
current sensing resistor and the load capacitor. The MOSFET with Sense output implementation is a Supply-based
Hot Swap implementation with the MOSFET connected between the supply and the current sensing resistor. The
full 5 V Hot Swap circuit is shown in Figure 14 below.
MOSFET with Sense Output Q536 N-Channel MOSFET supply-side Hot Swap switch supplies
power to +5V_HS and load capacitor C13. Sense output pro-
vides proportional current to drain current.
Gate Drive Resistor R5436 2.2 kΩ resistor, located close to MOSFET Q5, limits parasitic
oscillations at the gate of Q5. Works with C23 to slow switching
at Q5, limiting current ripple during hysteretic switching.
Current sense resistor R57363.30 Ω sense resistor for supply-side current monitoring with
IMON1 input of ASC, connected to Sense output of MOSFET
(Q5)
IMON1 Isolation Resistor R553, R5636 Zero Ω resistors – support population option for MOSFET with
Sense output versus standard MOSFET
Gate-Source Capacitor C2336 100 nF capacitor, works with R54 to slow switching at Q5, lim-
iting current ripple during hysteretic switching.
Load Capacitors C1316 680 µF 10 V Bulk capacitance emulates a Hot Swap load.
Discharge Resistors R6216 4.7 kΩ Resistor discharges load capacitor between Hot
Swaps.
LED Bias Resistor R63 6 3.3 kΩresistor limits the LED current for D10.
Red Indicator LED D10 6 LED to indicate Hot Swap has completed successfully.
Phoenix 2-Terminal Connector J6 6 +5V_HS terminal block connector
Current Sense Amplifier U216 ZXCT1009 current sense amplifier – provides output current
proportional to voltage across Vsense+ and Vsense-. Used for
demonstration purpose only, not required in application.
Current Sense Output Resistor R941620 kΩ resistor, sets output voltage at I_5V_HS test point to 1 V
/ 1A drain current of MOSFET.
NPN Fast Shutoff Transistor Q7 6 NPN transistor, provides fast pull-down of Q5/Q6 gate voltage,
enables fast shutdown from FPGA via ASC Interface connec-
tor during Hot Swap faults
Shutoff Transistor Pull-up Resistor R64 6 1 kΩ pull-up resistor – biases Q7 ON by default (shutting off
Q5/Q6).
Signals
+5V_SW 2, 6 5 V input voltage, from Power Supply circuit and J1
5V_HS_DRIVE 2, 6 HVOUT2 signal from ASC
ASC_5V_OC_SHUTDOWN 2, 6 FPGA PIO signal, from ASC Interface Connector
5V_HS_CURRENT_P 2, 6 Connected to IMON1A_P, positive current monitor terminal
5V_HS_CURRENT_N 2, 6 Connected to IMON1A_N, negative current monitor terminal
+5V_HS 2, 4, 6 5 V Hot Swap output voltage, provided to J6 terminal block,
ASC Interface Connector, and DCDC1 and 2 input voltage
Additional Test Points
I_5V_HS Current Sense Amplifier Output Voltage – 1 V per 1A
1.Not required for customer designs; this is only needed to support ASC device evaluation.
2.Only populate for 5 V Standard MOSFET Hot Swap. Populate only from either Note 2 or Note 3, never both.
3.Only populate for 5 V MOSFET with Sense output Hot Swap. Populate only from either Note 3 or Note 3, never both.
Component / Signals Ref. Des. Schematic
Sheet Description
19
ASC Breakout Board
Figure 14. 5 V Hot Swap Circuit
The Hot Swap circuit is designed to work with the Hot Swap component in the Platform Designer software. Platform
Designer will automatically generate the Hot Swap algorithm and device configuration based on user defined set-
tings for input voltage, MOSFET characteristics, load capacitance, and other parameters. For more detail on the
Hot Swap algorithm and working with Hot Swap in Platform Designer, see the References section.
The Hot Swap circuit can be broken into three sections in order to understand the operation of the overall circuit:
• Hot Swap
– Load-Based Using Standard MOSFET
– Supply-Based Using MOSFET with Sense Output
• Fast Shutdown Circuit
• Current Sensing Test Circuit
Load-Based Hot Swap (Standard MOSFET)
The circuit in Figure 15 illustrates the Load-based Hot Swap using Standard MOSFET. The Load-based Hot Swap
circuit has Q6 connected between the current sensing resistor R60 and the load capacitor. The N type MOSFET
Q6 is controlled by the high voltage output (HVOUT2) from the ASC. The gate resistor (R61) and gate-source
capacitor (C22) are used to maintain a soft turn on of Q6. The increased gate capacitance smooths out the current
during the hysteretic control stage (see the References section for more details on the Hot Swap behavior).
IMON
VMON6
HVOUT2
Population Options:
Standard MOSFET (Option A):
Q6, C22, R61,
R60, R58, R59
MOSFET w/ Sense (Option B):
Q5, R57, R55,
C23, R54, R56
sense X 600
ASC INT
Connector
Fast
Shutdown
VMON5
I_5V_HS - 1V per 1A sensed
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
MOSFET w/ Sense (Option B)
+5V_HS
+3.3V
5V_HS_DRIVE
Sheet [2]
+5V_HS Sheet [2,4]
5V_HS_CURRENT_P
Sheet [2]
5V_HS_CURRENT_NSheet [2]
ASC_5V_OC_SHUTDOWN
Sheet [2]
+5V_SWSheet [2,9,10]
kelvin
sense
Q5
BUK7C06-40AITE
R58
0
TP7
5V_IN
1
R54
2.2k R60
0.005
2W, 1%
TP17
I_5V_HS
1
TP16
5V_SDN
1
R59
0
C22
100nF
R62
4.7k
R61
2.2k
R57
3.30
1%
R55
0
R64
1k
C23
100nF
D10
Red
SM_LED_0603
R94
20k
1%
TP12
5V_HS
1
Q6
IRF7832
J6
2 Position Terminal Block
A
B
Q7
2N3904
R63
3.3k
R56
0
C13
680uF
10V
U2
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
20
ASC Breakout Board
Figure 15. 5 V Hot Swap - Load-Based, Standard MOSFET
The signals 5V_HS_CURRENT_P and 5V_HS_CURRENT_N are connected to the IMON1P and IMON1N signals
of the ASC. The sensing resistor R60 is connected through the zero Ω isolation resistors (R58, 59) to the ASC
using Kelvin connections and differential layout techniques to maximize the current sensing accuracy at the IMON1
inputs.
The +5V_HS signal is used by the Hot Swap function to monitor the load capacitor C13 voltage using VMON6 of
the ASC. The Hot Swap function monitors the load capacitor C13 voltage for the following reasons:
• to see that C13 is charging up and there is not a short or open in the circuit
• to see that C13 has reached a voltage where a higher current limit can be used
• to know when C13 is close to the 5 V supply voltage – Hot Swap is complete.
When Hot Swap is disabled R62 provides a discharge path for C13 to prepare the circuit for subsequent Hot
Swaps. LED D10 and bias resistor R63 give a visual indication that the Hot Swap process is complete.
Supply-Based Hot Swap (MOSFET with Sense Output)
The circuit in Figure 16 illustrates the Supply-based Hot Swap using a MOSFET with Sense output. (Components
from the Standard MOSFET Hot Swap are shown to illustrate the shared connections between the two circuits. Q6,
R58, R59, R60, R61, C22 should not be populated when the MOSFET with Sense output is used.) The MOSFET
with Sense output variation has Q5 connected to the supply side of R57. The SENSE output of Q5 provides a cur-
rent proportional to the current flowing through the MOSFET drain (the BUK7C06 shown in the schematic has a
typical drain current to sense current ratio of 615). The N type MOSFET Q5 is controlled by the HVOUT2 output
from the ASC. The gate resistor (R54) and gate-source capacitor (C23) are used to maintain a soft turn on of Q5.
The increased gate capacitance smooths out the current during the hysteretic control stage (see the References
section for more details on the Hot Swap behavior).
Shared
Connection with
MOSFET with Sense
Hot Swap
VMON6
+5V_HS
R58
0
R60
0.005
2W, 1%
R59
0
C22
100nF
R62
4.7k
R61
2.2k
D10
Red
SM_LED_0603
TP12
5V_HS
1
Q6
IRF7832
J6
2 Position Terminal Block
A
B
R63
3.3k
C13
680uF
10V
From 5V_SW
Supply Voltage
To ASC IMON 1P
Current Monitor
To ASC IMON 1N
Current Monitor
To Current Sense
Amplifier
From ASC
HVOUT2
21
ASC Breakout Board
Figure 16. 5 V Hot Swap - Supply Based, SENSEFET
The signals 5V_HS_CURRENT_P and 5V_HS_CURRENT_N are connected to the IMON1P and IMON1N signals
of the ASC. In the MOSFET with Sense output variation, R57 is used as the sensing resistor. R57 is tied between
the sense current output and the Kelvin source pin of MOSFET Q5. R57 is connected through the zero Ω isolation
resistors (R55, 56) to the ASC using Kelvin connections and differential layout techniques to maximize the current
sensing accuracy at the IMON1 inputs.
VMON6 is used by the Hot Swap function to monitor the load capacitor C13 voltage. The Hot Swap function moni-
tors the load capacitor C13 voltage for the following reasons:
• to see that C13 is charging up and there is not a short or open in the circuit
• to see that C13 has reached a voltage where a higher current limit can be used
• to know when C13 is close to the 5 V supply voltage – Hot Swap is complete.
When Hot Swap is disabled R62 provides a discharge path for C13 to prepare the circuit for subsequent Hot
Swaps. LED D10 and bias resistor R63 give a visual indication that the Hot Swap process is complete.
Fast Shutdown Circuit
The fast shutdown circuit for the 5 V Hot Swap is shown in Figure 17 below. The ASC_5V_OC_SHUTDOWN signal
is output from the main FPGA board via the ASC Interface Connector. The ASC_5V_OC_SHUTDOWN signal is
active high, and by default pulled up to 3.3 V by R64. When ASC_5V_OC_SHUTDOWN is high, Q7 is biased on.
This will pull the MOSFET gate low, holding the MOSFET off (see the Hot Swap circuit description above for more
details). When ASC_5V_OC_SHUTDOWN is driven low, Q7 will be biased off. When Q7 is turned off, the Hot
Swap MOSFET will be controlled by the ASC HVOUT2 voltage. The fast shutdown feature can be implemented
using the Hot Swap component in Platform Designer. Assign the FPGA PIO connected to
ASC_5V_OC_SHUTDOWN on the main FPGA board to the Fast Shut Down feature in Platform Designer. See the
Reference section for more details.
IMON
VMON6
Population Options:
Standard MOSFET (Option A):
Q6, C22, R61,
R60, R58, R59
MOSFET w/ Sense (Option B):
Q5, R57, R55,
C23, R54, R56
sense X 600
VMON5
MOSFET w/ Sense (Option B)
+5V_HS
+5V_HS Sheet [2,4]
5V_HS_CURRENT_P
Sheet [2]
5V_HS_CURRENT_NSheet [2]
+5V_SW
Sheet [2,9,10]
kelvin
sense
Q5
BUK7C06-40AITE
R58
0
TP7
5V_IN
1
R54
2.2k R60
0.005
2W, 1%
R59
0
C22
100nF
R62
4.7k
R61
2.2k
R57
3.30
1%
R55
0
C23
100nF
D10
Red
SM_LED_0603
TP12
5V_HS
1
Q6
IRF7832
J6
2 Position Terminal Block
A
B
R63
3.3k
R56
0
C13
680uF
10V
Note: Components not populated
on breakout board
To ASC IMON1 and
Current Sense
Amplifier
From ASC
HVOUT2
From ASC
HVOUT2
22
ASC Breakout Board
Figure 17. 5 V Hot Swap – Fast Shutdown Circuit
Current Sense Feedback Circuit
The 5 V Hot Swap circuit on the ASC Breakout board includes a current sense feedback circuit, shown in
Figure 18. The purpose of this circuit is for demonstration and evaluation only, it does not need to be included on a
customer application board. The current sense amplifier (U2 – ZXCT1009 from Diodes, Inc) provides an output
current proportional to the voltage measured over R60. Based on the R60 resistance (5 mΩ) and the R94 resis-
tance (20 kΩ), the ratio of output voltage at TP17 (I_5V_HS) to sensed current across R60 is about 1 V / 1A (this
ratio is also maintained when Q5 and R57 are used instead of Q6 and R60). The test point I_5V_HS can be moni-
tored on an oscilloscope to confirm the Hot Swap operation and evaluate the current behavior during Hot Swap.
The internal current sense amplifier in the ASC is used in the Hot Swap algorithm, the circuit formed by U2 and
R94 is only included to provide observable current feedback during the evaluation stage.
Figure 18. 5 V Hot Swap - Current Sense Feedback Circuit
ASC INT
Connector
Fast
Shutdown
+3.3V
ASC_5V_OC_SHUTDOWN
Sheet [2]
TP16
5V_SDN
1
R64
1k
Q7
2N3904
To Hot Swap
MOSFET Gate
I_5V_HS - 1V per 1A sensed
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
R58
0
R60
0.005
2W, 1%
TP17
I_5V_HS
1
R59
0
R94
20k
1%
U2
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
From Hot Swap
Standard MOSFET
To ASC IMON 1P
Current Monitor
To ASC IMON 1N
Current Monitor
To 5V_HS Load
Capacitor
23
ASC Breakout Board
12 V Hot Swap (Not Populated)
The ASC Breakout Board provides a set of footprints and connections for implementing a 12 V Hot Swap circuit
using the ASC’s built in hardware. Table 9 lists the key elements associated with 12 V Hot Swap operation on the
ASC Breakout Board.
Table 9. 12 V Hot Swap Components and Signals
Component / Signals Ref. Des. Schematic
Sheet Description
Components Not Populated on Breakout Board
Voltage Divider Resistor R65, R66 7 3 kΩ (R65) and 1.02 kΩ (R66) to divide +12V_SW rail down to
below 5.9 V limit for VMON input
Zener Diode D11 7 Zener Diode for VMON input protection. Limits VMON9 input
during transients and overvoltage.
MOSFET Switch Q92, Q10 7 N-Channel MOSFET Supply-side Hot Swap switches supply
power to +12V_HS and load capacitor C15.
Gate Drive Resistor R712, R72 7 2.2 kΩ resistors, located close to MOSFETs Q9 & Q10, limits
parasitic oscillations at the gates of Q9 & Q10. Works with C2,
C21 to slow switching at Q9 & Q10, limiting current ripple dur-
ing hysteretic switching.
Gate-Source Capacitor C202, C2127 100nF capacitors, works with R71 & R72 to slow switching at
Q9 & Q10, limiting inrush current during Hot Swap start and
current ripple during hysteretic switching.
Current Sense Resistor R73 7 10 mΩ 3 W resistor for load side current monitoring with
HIMON input of ASC
HIMON Snubbing Resistor R742, R7527 Snubber resistors (paired with C16, C17) protect HIMON input
from momentary overvoltage, including inductive flyback volt-
ages when Q9 and Q10 are turned off. Population option to
support standard MOSFET Q9 versus MOSFET with Sense
output Q11.
MOSFET with Sense Output Q1137 N-Channel MOSFET supply-side Hot Swap switch supplies
power to +12V_HS and load capacitor C15 with Q10. Sense
output provides proportional current to drain current.
Gate Drive Resistor R6737 2.2 kΩ resistor, located close to MOSFET Q11, limits parasitic
oscillations at the gate of Q11. Works with C26 to slow switch-
ing at Q11, limiting current ripple during hysteretic switching.
Current sense resistor R68376.20 Ω resistor for supply-side current monitoring with HIMON
input of ASC using MOSFET with Sense output
HIMON Snubbing Resistor R693, R7037 Snubber resistors (paired with C16, C17) protect HIMON input
from momentary overvoltage, including inductive flyback volt-
ages when Q10 and Q11 are turned off. Population option to
support MOSFET with Sense output Q11 versus standard
MOSFET Q9.
Gate-Source Capacitor C2637 100 nF capacitor, works with R67 to slow switching at Q11,
limiting inrush current during Hot Swap start and current ripple
during hysteretic switching.
HIMON Snubbing Capacitor C16, C17 7 Snubber capacitors (paired with snubbing resistors) protect
HIMON input from momentary overvoltage, including inductive
flyback voltages when MOSFETs are turned off.
Load Capacitors C1517 1000 µF 25 V Bulk capacitance emulates a Hot Swap load.
Discharge Resistors R761710 kΩ Resistor discharges load capacitor between Hot Swaps.
LED Bias Resistor R77 7 10 kΩ resistor limits the current through LED D12
Red Indicator LED D12 7 LED to indicate 12 V Hot Swap is complete
Phoenix 2-Terminal Connector J8 7 +12V_HS terminal block connector
24
ASC Breakout Board
The 12 V Hot Swap circuit is designed to support two separate implementations. The standard MOSFET imple-
mentation uses standard power MOSFETs (Q9 and Q10) and a 10 mΩ sense resistor (R73). The MOSFET with
Sense output implementation uses a power MOSFET with current sense output (Q11) along with a standard power
MOSFET (Q10) and a 6.20 Ω sense resistor (R68). Both circuits are Supply-based Hot Swap implementations with
the MOSFETs connected between the supply and the current sensing resistors. The full 12 V Hot Swap circuit is
Charge Pump Supply Diode D13 7 Diode provides path for current from +12V_SW supply to
charge C18 when HVOUT1 = 0 V
NPN Bias Resistor R78 7 4.7 MΩ resistor limits the base current of NPN transistor, main-
tains NPN base voltage close to +12V_SW supply voltage
NPN Transistor – SOT-23 Q17 7 NPN transistor, only biased ON when C18 voltage rises above
+12V_SW supply voltage. Transistor stays off when HVOUT1
and charge pump are disabled – protects Q12 from thermal
stress
HVOUT Protection Zener Diode D14 7 Zener Diode for HVOUT1 protection. Limits HVOUT1 voltage
in case of transients on +12V_SW supply
Charge Pump Serial Capacitor C18 7 100 nF capacitor, works with D13 to add +12V_SW voltage to
HVOUT1 voltage
Charge Pump Diode D15 7 Diode provides path for current from C18 (via Q17) to charge
C19 to boosted voltage
Charge Pump Buffer Capacitor C19 7 Stores boosted charge pump voltage. Boosted voltage drives
MOSFET gate to fully conduct +12V_SW input supply to
+12V_HS and C15 load capacitor (controlled by Hot Swap
algorithm).
Charge Pump Discharge Resistor R80 7 10 kΩ resistor, provides discharge path for C19 when Hot
Swap is disabled
NPN Fast Shutoff Transistor Q12 7 NPN transistor, provides fast pull-down of Q9/Q10/Q11 gate
voltages, enables fast shutdown from FPGA via ASC Interface
connector during Hot Swap faults
Shutoff Transistor Pull-up Resistor R79 7 1 kΩ pull-up resistor – biases Q12 ON by default (shutting off
Q9/Q10/Q11).
Current Sense Amplifier U317 ZXCT1009 current sense amplifier – provides output current
proportional to voltage across Vsense+ and Vsense-. Used for
demonstration purpose only, not required in application.
Current Sense Output Resistor R951720 kΩ resistor, sets output voltage at I_12V_HS test point to 1
V / 1A drain current of MOSFET.
Signals
+12V_SW 7, 9 12 V input voltage, from Power Supply circuit and J2/J3
MON_12V_IN 2, 7 12 V input voltage, divided down below 5.9 V, connected to
VMON9
CHARGE_PUMP 2, 7 HVOUT1 signal from ASC, switched signal to charge pump cir-
cuit
ASC_12V_OC_SHUTDOWN 2, 7 FPGA PIO signal, from ASC Interface Connector
MON_12V_HS_VOLTAGE 5, 7 Connected to HIMONN_HVMON, negative current monitor ter-
minal and high voltage monitor input
MON_12V_HS_CURRENT 2, 7 Connected to HIMONP, positive current monitor terminal
Separate Test Points
I_12V_HS 7 Current Sense Amplifier Output Voltage – 1 V per 1A
PUMP_V 7 Charge Pump output voltage for Gate Drive
1.Not required for customer designs; this is only needed to support ASC device evaluation.
2.Only populate for 12 V standard MOSFET Hot Swap. Populate only from either Note 2 or Note 3, never both.
3.Only populate for 12 V MOSFET with Sense output Hot Swap. Populate only from either Note 3 or Note 3, never both.
Component / Signals Ref. Des. Schematic
Sheet Description
25
ASC Breakout Board
shown in Figure 19 below.
Figure 19. 12 V HS Circuit
The Hot Swap circuit is designed to work with the Hot Swap component in the Platform Designer software. Platform
Designer will automatically generate the Hot Swap algorithm and device configuration based on user defined set-
tings for input voltage, MOSFET characteristics, load capacitance, and other parameters. For more detail on the
Hot Swap algorithm and working with Hot Swap in Platform Designer, see the References section.
The Hot Swap circuit can be broken into five sections in order to understand the operation of the overall circuit:
• Input Voltage Monitor
• Charge Pump
• Supply-Based Hot Swap
– Using Standard MOSFET
– Using MOSFET with Sense Output
• Fast Shutdown Circuit
• Current Sensing Test Circuit
Input Voltage Monitor
VMON9 is used to monitor the input voltage. The voltage monitors have a max input voltage of 5.9 V, so the circuit
in Figure 20 below is required to monitor the 12 V input rail. R65 and R66 divide down the voltage within the oper-
ating range of the VMON. (The voltage at VMON9 will be approximately 25% of the voltage at +12V_SW). These
resistors can be input into the Platform Designer tool in the Voltage view, and platform designer will automatically
scale the trip points up to the input of the resistive divider.
D11 is included in the circuit to protect the voltage monitor input from transient voltages above the 5.9 V input volt-
age. The clamp voltage of 5.1 V is well below the 5.9 V max operating voltage for the VMON channel.
HIMON
ASC INT
Connector
VMON9
HVOUT1
sense X 600
I_12V_HS - 1V per 1A sensed
Population Options:
Standard MOSFET (Option A):
Q9, C20, R71,
R74, R75, C21
MOSFET w/ Sense (Option B):
Q11, R68, C26,
R69, R70, R67
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
MOSFET w/ Sense (Option B)
Note: Components not populated
on breakout board
+12V_HS
PUMP_V
+12V_SW
+3.3V
+12V_SW
MON_12V_HS_CURRENTSheet [2]
ASC_12V_OC_SHUTDOWN
CHARGE_PUMP
MON_12V_INSheet [2]
+12V_HS
MON_12V_HS_VOLTAGE Sheet [2]
+12V_SW
C16
10nF
R76
10k
R72
2.2k
R70
24
Q12
2N3904
R68
6.20
1%
R95
10k
1%
C17
10nF
C15
1000uF
25V
R77
10k
D12
Red
SM_LED_0603
Q9
IRF7832
C21
100nF
TP18
I_12V_HS
1
R71
2.2k
R65
3k
C18
100nF
C19
10nF
D13
1N4148
J8
2 Position Terminal Block
A
B
R67
2.2k
R74
24
TP14
12V_HS
1
C20
100nF
TP15
12V_SDN
1
R69
24
R79
1k
kelvin
sense
Q11
BUK7C06-40AITE
TP19
PUMP_V
1
R73
0.01
3W
1%
Q17
2N3906
Q10
IRF7832
D11
MMSZ5231BS-7-FL
5.1V
D14
MMSZ5240B-7-F
10V
R66
1.02k
TP13
12V_IN
1
U3
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
D15
1N4148
C26
100nF
R80
510k
R78
4.7M
R75
24
26
ASC Breakout Board
Figure 20. 12 V Hot Swap - Input Voltage Monitor Circuit
Charge Pump
The 12 V Hot Swap circuit requires a charge pump to boost the gate voltage to around 20 V to fully turn on the
MOSFET to conduct 12 V. The circuit shown in Figure 21 is used to implement this external charge pump using
diodes, capacitors, and a transistor.
Figure 21. 12 V Hot Swap - Charge Pump Circuit
The CHARGE_PUMP signal is output from HVOUT1. The Hot Swap component in Platform Designer will configure
HVOUT1 in the switched mode output, so that the output will toggle between 12 V and 0 V with an 81.25% duty
cycle at 31.25 kHz. D14 is connected to the CHARGE_PUMP signal to protect the HVOUT1 signal from transient
voltages which may be present on the +12V_SW rail. D14 will clamp transient voltages above 10 V, keeping the
HVOUT1 voltage below the 13.2 V maximum operating voltage.
When the CHARGE_PUMP signal is at 0 V, C18 will be charged to the +12V_SW voltage through diode D13. At
this time, PNP transistor Q17 will be off, due to the emitter-base voltage being below the Q17 cutoff voltage (the
emitter voltage will be around +12V_SW minus 0.7 V, while the base voltage is +12V_SW).
When the CHARGE_PUMP signal toggles up to 12 V, the voltage on C18 will be added to the CHARGE_PUMP
output voltage, resulting in the generation of approximately 22 V at the junction of C18 and D13. This voltage will
result in an emitter-base voltage that will bias on Q17 (the emitter voltage will be around 22 V, while the base volt-
age is +12V_SW). The 22 V will conduct through Q17 and D15 to charge up C19. C19 stores the voltage which is
seen at the gate of the Hot Swap MOSFETs, and the MOSFETs will turn on as C19 is charged up. R80 provides a
VMON9
+12V_SW
MON_12V_IN
+12V_SW
R65
3k
D11
MMSZ5231BS-7-FL
5.1V
R66
1.02k
TP13
12V_IN
1
To Supply-Based
Hot Swap
Sheet [9, 10]
ASC INT
Connector
HVOUT1
PUMP_V
+12V_SW
+3.3V
ASC_12V_OC_SHUTDOWN
CHARGE_PUMP
Q12
2N3904
C18
100nF
C19
10nF
D13
1N4148
TP15
12V_SDN
1
R79
1k
TP19
PUMP_V
1
Q17
2N3906
D14
MMSZ5240B-7-F
10V
D15
1N4148
R80
510
k
R78
4.7M
To Supply-Based
Hot Swap
MOSFET gate
27
ASC Breakout Board
discharge path for C19 when the charge pump is disabled. The PUMP_V test point can be used for monitoring the
charge pump voltage level.
Supply-Based Hot Swap (Standard MOSFET)
The circuit in Figure 22 illustrates the Supply-Based Hot Swap using Standard MOSFETs. The Supply-Based Hot
Swap circuit has Q9 and Q10 connected between the supply and the current sensing resistor R73. The N type
MOSFETs Q9 and Q10 are controlled by the output of the charge pump circuit (the charge pump is controlled by
HVOUT1). Q9 and Q10 have their sources tied together. Q9 is connected in such a way that it only conducts from
the supply to the load when the gate is biased and the MOSFET is on. Q10 is connected in such a way that it only
conducts from the load to the supply when the gate is biased and the MOSFET is on. Connecting the MOSFETs in
this way ensures that the Hot Swap algorithm can fully control current flowing in to charge up the load capacitor
C15 and the current flowing out from C15 to the input supply (in case of input supply brown out). The gate resistors
(R71, R72) and gate-source capacitors (C20, C21) are used to maintain a soft turn on of Q9 and Q10. The
increased gate capacitance limits inrush current during the initial Hot Swap turn on and smooths out the current
during the hysteretic control stage (see the References section for more details on the Hot Swap behavior).
Figure 22. 12 V Hot Swap - Standard MOSFET Circuit
The signals MON_12V_HS_VOLTAGE and MON_12V_HS_CURRENT are connected to the HIMONN_HVMON
and HIMONP signals of the ASC. These signals are protected from momentary over-voltage (including inductive
flyback voltages when Q9 and Q10 are turned off) by the resistor (R74, R75) and capacitor (C16, C17) pair snub-
ber circuit between the sensing resistor and the device inputs. The sensing resistor R73 is connected through the
snubber circuit using Kelvin connections and differential layout techniques to maximize the current sensing accu-
racy at the HIMON inputs.
The MON_12V_HS_VOLTAGE signal is also used by the Hot Swap function to monitor the load capacitor C15 volt-
age using the HVMON of the ASC. The Hot Swap function monitors the load capacitor C15 voltage for the following
reasons:
• to see that C15 is charging up and there is not a short or open in the circuit
• to see that C15 has reached a voltage where a higher current limit can be used
• to know when C15 is close to the 12 V supply voltage – Hot Swap is complete.
When Hot Swap is disabled R76 provides a discharge path for C15 to prepare the circuit for subsequent Hot
Swaps. LED D12 and bias resistor R77 give a visual indication that the Hot Swap process is complete.
HIMON
+12V_HS
MON_12V_HS_CURRENTSheet [2]
+12V_HS
MON_12V_HS_VOLTAGE Sheet [2]
C16
10nF
R76
10k
R72
2.2k
C17
10nF
C15
1000uF
25V
R77
10k
D12
Red
SM_LED_0603
Q9
IRF7832
C21
100nF
R71
2.2k
J8
2 Position Terminal Block
A
B
R74
24
12V_HS
1
C20
100nF
R73
0.01
3W
1%
Q10
IRF7832
R75
24
Shared Connection with
MOSFET with Sense
From 12V_SW
Supply Voltage
Shared
Connection with
MOSFET with Sense
Shared
Connection with
MOSFET with Sense
From Charge
Pump Circuit
To Current
Sense Amplifier
28
ASC Breakout Board
Supply-Based Hot Swap (MOSFET with Sense Output)
The circuit in Figure illustrates the Supply-based Hot Swap using a MOSFET with Sense output. (Components
from the Standard MOSFET Hot Swap are shown also to illustrate the shared connections between the two cir-
cuits. Q9, R71, R74, R75, C20, and C21 are not used with the MOSFET with Sense output). The MOSFET with
Sense output variation has Q11 and R68 connected with Q10 and R73, with Q11 on the supply side of R68. The
SENSE output provides a current proportional to the current flowing through the MOSFET drain (the BUK7C06
shown in the schematic has a typical drain current to sense current ratio of 615). The MOSFET with Sense output
(Q11) takes the place of Q9 in this variation. The N type MOSFETs Q10 and Q11 are controlled by the output of the
charge pump circuit (the charge pump is controlled by HVOUT1). Q10 and Q11 have their sources tied together.
Q11 is connected in such a way that it only conducts from the supply to the load when the gate is biased and the
MOSFET is on. Q10 is connected in such a way that it only conducts from the load to the supply when the gate is
biased and the MOSFET is on. Connecting the MOSFETs in this way ensures that the Hot Swap algorithm can fully
control current flowing in to charge up the load capacitor C15 and the current flowing out from C15 to the input sup-
ply (in case of input supply brown out). The gate resistors (R67, R72) and gate-source capacitors (C26, C21) are
used to maintain a soft turn on of Q11 and Q10. The increased gate capacitance limits inrush current during the ini-
tial Hot Swap turn on and smooths out the current during the hysteretic control stage (see the References section
for more details on the Hot Swap behavior).
Figure 23. 12 V Hot Swap SENSEFET Circuit
The signals MON_12V_HS_VOLTAGE and MON_12V_HS_CURRENT are connected to the HIMONN_HVMON
and HIMONP signals of the ASC. These signals are protected from momentary over-voltage (including inductive
flyback voltages when Q11 and Q10 are turned off) by the resistor (R69, R70) and capacitor (C16, C17) pair snub-
ber circuit between the sensing resistor and the device inputs. In the MOSFET with Sense output variation, R68 is
used as the sensing resistor. R68 is tied between the sense current output and the Kelvin source pin of MOSFET
Q11. R68 is connected through the snubber circuit using differential layout techniques to maximize the current
sensing accuracy at the HIMON inputs. (Note that a resistor must be populated at R73, even in the MOSFET with
Sense output variation. R74 and R75 are not populated. This allows the current to flow to the load capacitor without
affecting the sense current measurement by the HIMON in ASC).
HIMON
sense X 600
Population Options:
Standard MOSFET (Option A):
Q9, C20, R71,
R74, R75, C21
MOSFET w/ Sense (Option B):
Q11, R68, C26,
R69, R70, R67
MOSFET w/ Sense (Option B)
Note: Components not populated
on breakout board
+12V_HS
MON_12V_HS_CURRENTSheet [2]
+12V_HS
MON_12V_HS_VOLTAGE Sheet [2]
C16
10nF
R76
10k
R72
2.2k
R70
24
R68
6.20
1%
C17
10nF
C15
1000uF
25V
R77
10k
D12
Red
SM_LED_0603
Q9
IRF7832
C21
100nF
R71
2.2k
J8
2 Position Terminal Block
A
B
R67
2.2k
R74
24
TP14
12V_HS
1
C20
100nF
R69
24
Q11
BUK7C06-40AITE
R73
0.01
3W
1%
Q10
IRF7832
C26
100nF
R75
24
From 12V_SW
Supply Voltage
From Charge
Pump Circuit
To Current Sense
Amplifier
29
ASC Breakout Board
The MON_12V_HS_VOLTAGE signal is also used by the Hot Swap function to monitor the load capacitor C15 volt-
age using the HVMON of the ASC. The Hot Swap function monitors the load capacitor C15 voltage for the following
reasons:
• to see that C15 is charging up and there is not a short or open in the circuit
• to see that C15 has reached a voltage where a higher current limit can be used
• to know when C15 is close to the 12 V supply voltage – Hot Swap is complete.
When Hot Swap is disabled R76 provides a discharge path for C15 to prepare the circuit for subsequent Hot
Swaps. LED D12 and bias resistor R77 give a visual indication that the Hot Swap process is complete.
Fast Shutdown Circuit
The fast shutdown circuit for the 12 V Hot Swap is shown in Figure 24 below. The ASC_12V_OC_SHUTDOWN sig-
nal is output from the main FPGA board via the ASC Interface Connector. The ASC_12V_OC_SHUTDOWN signal
is active high, and by default pulled up to 3.3 V by R79. When ASC_12V_OC_SHUTDOWN is high, Q12 is biased
on. This will pull the MOSFET gate low, holding the MOSFET off. When ASC_12V_OC_SHUTDOWN is driven low,
Q12 will be turned off. When Q12 is turned off, the Hot Swap MOSFET(s) will be controlled by the charge pump
voltage. The fast shutdown feature can be implemented using the Hot Swap component in Platform Designer.
Assign the FPGA PIO connected to ASC_12V_OC_SHUTDOWN on the main FPGA board to the Fast Shut Down
feature in Platform Designer. See the References section for more details.
Figure 24. 12 V Hot Swap - Fast Shutdown Circuit
Current Sense Feedback Circuit
The 12 V Hot Swap circuit on the ASC Breakout board includes a current sense feedback circuit, shown in
Figure 25. The purpose of this circuit is for demonstration and evaluation only, it does not need to be included on a
customer application board. The current sense amplifier (U3 – ZXCT1009 from Diodes, Inc) provides an output
current proportional to the voltage measured over R73. Based on the R73 resistance (10 mΩ) and the R95 resis-
tance (10 kΩ), the ratio of output voltage to sensed current across R73 is about 1 V / 1A (this ratio is also main-
tained when Q11 and R68 are used instead of Q9 and R73). The test point I_12V_HS can be monitored on an
oscilloscope to confirm the Hot Swap operation and evaluate the current behavior during Hot Swap. The internal
current sense amplifier in the ASC is used in the Hot Swap algorithm, the circuit formed by U3 and R95 is only
included to provide observable current feedback during the evaluation stage.
ASC INT
Connector
+3.3V
ASC_12V_OC_SHUTDOWN
Q12
2N3904
TP15
12V_SDN
1
R79
1k
Sheet [2]
To Supply-Based
Hot Swap
MOSFET Gate
30
ASC Breakout Board
Figure 25. 12 V Hot Swap - Current Sense Feedback Circuit
Prototype Area
The ASC Breakout Board provides multiple areas for prototyping circuits with the ASC. The Through Hole Proto-
type Area (see Sheet 10 of the schematic) is accessible from both the top and bottom side of the board. As shown
in Figure 26, the Through Hole Prototype Area is arranged as a grid on the breakout board. The top three rows pro-
vide ten connections each to the +12V_SW, +5V_SW and +3.3 V voltage rails. The next eight rows provide ten
open connections each – these can be used for mounting and connecting through hole components. The bottom
row provides ten connections to the ground plane of the breakout board.
HIMON
I_12V_HS - 1V per 1A sensed
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
MON_12V_HS_CURRENT
MON_12V_HS_VOLTAGE
C16
10nF
R95
10k
1%
C17
10nF
TP18
I_12V_HS
1
R74
24
R73
0.01
3W
1%
U3
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
R75
24
Shared
Connections with
MOSFET with Sense
Hot Swap
+12V_SW from
Supply and
MOSFETs
+12_HS to Load
Capacitor
31
ASC Breakout Board
Figure 26. Through Hole Prototype Area
The ASC Breakout Board also provides a surface-mount prototyping area on the bottom side of the board. The sur-
face mount area is near the through hole prototyping area and provides a set of common footprints for resistors,
capacitors, diodes, transistors and other integrated circuits as shown in Table 10. The schematic (Sheet 10)
includes placeholder parts used to generate the footprints for the prototype area as shown in Figure 27. These sur-
face mount footprints are unconnected – the user will need to connect any components placed on these footprints.
Figure 27. Surface Mount Prototype Area
Table 10. SMD Prototype Area - Footprint Summary
Footprint Type Quantity Reference Designators Common Use
SOIC-8 2 Q20, Q21 Power MOSFETs, other ICs
SOT-23 4 Q22, Q23, Q24, Q25 NPN, PNP, MOSFET Transistors, and other
ICs
SOT-223 2 Q26, Q27 Power MOSFETs
SMD-0805 12 R100, R101, R102, R103, R104, R105,
R106, R107, R108, R109, R110, R111
Resistors, Inductors, Capacitors, and
Diodes
SMD-2512 2 R112, R113 Current Sense Resistors (Shunts)
Through Hole Prototype Area
+12V_SW
Sheet [7]
+5V_SW
Sheet [2,6]
+3.3V
Sheet [2,3,4,5,6,7,8,9]
AF22
AF12
AH21
AJ15
AE18
AH11
AB13
AC20
AJ22
AF13
AJ21
AJ16
AA11
AG20
AB14
AD11
AG13
AJ17
AE19
AB15
AK21
AH12 AD12
AH22
AE13
AJ18
AF20
AH13
AB16
AD13
AK22
AE14
AJ19
AA12
AH14
AB17
AD14AG14
AK11
AA13
AB18
AH15 AD15
AF14
AJ20
AA14
AH16
AB19
AD16
AG15
AK12
AA15
AB20
AD17AH17
AE15
AK13
AA16
AC11
AD18AH18
AE16
AK14
AA17
AC12
AD19
AA21
AE17
AK15
AA20
AC15
AA22
AD20
AB21
AF16
AH19
AA18
AK17
AC13
AB22
AG11
AC21
AJ11
AF17
AK18
AA19
AC14
AC22
AD21
AF11
AH20
AF15
AK16
AG17
AC16
AE22
AG12
AE21
AG16
AJ12
AE20
AC17
AD22
AE11
AG21
AJ13
AF18AG18
AB11
AK19
AC18
AG22
AF21
AE12
AJ14
AF19
AB12
AG19 AC19
AK20
SOT-23 Package Prototype Area SMD SOT-223 Prototype Area
SOIC-8 Package Prototype Area
Q27
NDT3055LCT
DNI
Q20
IRF7832
DNI
Q22
2N3904
DNI
Q21
IRF7832
DNI
Q23
2N3904
DNI
Q24
2N3904
DNI
Q25
2N3904
DNIQ26
NDT3055LCT
DNI
SMD 2512 Resistor
Package Prototype Area
SMD 0805 Cs, Ds, or Rs Prototype Area
R104
1k
DNI
R105
1k
DNI
R106
1k
DNI
R111
1k
DNI
R107
1k
DNI
R112
1k
DNI
R113
1k
DNI
R108
1k
DNI
R100
1k
DNI
R101
1k
DNI
R109
1k
DNI
R103
1k
DNI
R102
1k
DNI
R110
1k
DNI
32
ASC Breakout Board
Mechanical Specifications
Dimensions: 6 in. [L] x 3.5 in. [W] x 1 in. [H]
Environmental Specifications
The breakout board must be stored between -40°C and 100°C. The recommended operating temperature is
between 0°C and 55°C.
Electrical Specifications
• 12 V Input +/- 15% (Input current requirement depending on Hot Swap settings and DC-DC Load Resistance)
• 5 V Input +/- 10% (Input current requirement depending on Hot Swap settings and DC-DC Load Resistance)
• 3.3 V Input +/- 5% (Breakout board current draw 100 mA typical)
References
•EB93, Platform Manager 2 Evaluation Board User Guide
• DS1042, L-ASC10 Data Sheet
• TN1225, Platform Manager 2 Hardware Checklist
• Platform Designer 3.1 User Guide
• AN6041, Extending the VMON Input Range of Power/Platform Management Devices
• AN6074, Interfacing the Trim Output of Power Manager II Devices to DC-DC Converters
Technical Support Assistance
Submit a technical support case through www.latticesemi.com/techsupport.
Revision History
© 2015 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as
listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of
their respective holders. The specifications and information herein are subject to change without notice.
Date Version Change Summary
July 2015 1.0 Initial release.
33
ASC Breakout Board
Appendix A. Schematics
Figure 28. ASC System Block Diagram
5
5
4
4
3
3
2
2
1
1
D D
C C
B B
A A
Contents
ASC System Block Diagram
Date:
Size Schematic Rev
ofSheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
111
ASC System Block Diagram
ASC Breakout Board B
of
Bd
Project
of
Bd
Proj t
34
ASC Breakout Board
Figure 29. Analog Sense and Control
5
5
4
4
3
3
2
2
1
1
DD
C C
B B
AA
ASC TEST POINTS
Analog Sense and Control
Mandatory ASC Jumper 2 to 3
Optional ASC Jumper 1 to 2
ASC I2C Address Select
1
3
2
4
5
7
6
ASC Interface Connector
0
ASC_WDAT
ASC_RDAT
ASC_WRCLK
LED9
LED3
LED4
LED5
LED6
LED1
LED2
LED10
VMON6
VMON5
LED8
VMON1
VMON2
VMON3
VMON4
VMON5
VMON6
POT1
POT2
MON_12V_IN
TRIM_DCDC1
TRIM_DCDC2
TRIM_DCDC3
TRIM_DCDC4
CHARGE_PUMP
5V_HS_DRIVE
HVOUT4
LED1
LED2
LED3
LED4
LED5
LED6
LED8
LED9
LED10
GS_VMON1
ASC_WDAT
ASC_RDAT
ASC_WRCLK
ASC_RESETb
GS_VMON2
GS_VMON3
GS_VMON4
MON_12V_HS_CURRENT
MON_12V_HS_VOLTAGE
TEMP_SENSE1P
TEMP_SENSE1N
TEMP_SENSE2P
TEMP_SENSE2N
HVOUT4
I2C_SCL
I2C_SDA
VMON5
HVOUT3
HVOUT3
ASC_RESET
MANDATORY_RESET
ASC_RESETb
I2C_ADDR
ASC_WDAT
ASC_RDAT
ASC_WRCLK
MANDATORY_RESET
ASC_RESET
I2C_WRITE_EN
+5V_HS
+12V_HS
I2C_SCL
I2C_SDA
5V_OC_SENSE
12V_OC_SENSE
I2C_WRITE_EN
I2C_ADDR
LED2
LED3
5V_HS_CURRENT_N
5V_HS_CURRENT_P
VMON6
ASC_CLK
ASC_CLK
ASC_CLK
I2C_SCL
I2C_SDA
+3.3V_ASC
+3.3V_ASC
+3.3V
+3.3V
+3.3V
VMON1
Sheet [3]
VMON2
Sheet [3]
VMON3
Sheet [4]
VMON4
Sheet [4]
TRIM_DCDC1 Sheet [3]
TRIM_DCDC2 Sheet [3]
TRIM_DCDC3 Sheet [4]
TRIM_DCDC4 Sheet [4]
POT2
Sheet [5]
POT1
Sheet [5]
TEMP_SENSE1P
Sheet [5]
TEMP_SENSE1N
Sheet [5]
TEMP_SENSE2P
Sheet [5]
TEMP_SENSE2N
Sheet [5]
CHARGE_PUMP Sheet [7]
ASC_12V_OC_SHUTDOWNSheet [7]
5V_HS_CURRENT_N
Sheet [6]
5V_HS_CURRENT_P
Sheet [6]
MON_12V_HS_VOLTAGE
Sheet [7]
MON_12V_HS_CURRENT
Sheet [7]
5V_HS_DRIVE Sheet [6]
LED[1:10] Sheet [3,4,5,8]
GS_VMON1
Sheet [3]
GS_VMON2
Sheet [3]
GS_VMON3
Sheet [4]
GS_VMON4
Sheet [4]
+5V_HSSheet [2,4,6]
+12V_HSSheet [3,7]
+3.3VSheet [3,4,5,6,7,8,9,10]
+11.3VSheet [9]
ASC_5V_OC_SHUTDOWNSheet [6]
MON_12V_IN
Sheet [7]
+5V_HS
Sheet [2,4,6]
+5V_SW
Sheet [6,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
112
Analog Sense and Control
ASC Breakout Board B
TRIM2
GPIO5
SW3E
512
TRIM3
R3
10k
GPIO6
R4 0
SW3D
413
ASC_CLK
HVOUT3
HIMONP
VMON1
R9 1K
R1 24
TRIM4
SW3F
611
GPIO8
VMON2
HIMONN_HVMON
SCL
C3
150pF
RESET
GPIO9
SDA
HVOUT1
R2 24 RDAT
VMON3
SW3H
89
IMONP
GPIO10
VMON4
WCLK
HVOUT2
C4
150pF
IMONN
SW3G
710
WDAT
C1
100nF
VMON6
VMON1_GS
R10 18.0K
HVOUT4
VMON5
J10
CONN DSUB 25-P
1
14
2
15
3
16
4
17
5
18
6
19
7
20
8
21
9
22
10
23
11
24
12
25
13
C2
100nF
VMON2_GS
R11 14.0K
GPIO1
VMON3_GS
VMON8
R7 0
VMON4_GS
R12 10.0K
VMON7
SW3A
116
GPIO2
TMON1P
R5 270
R13 7.00K
R6 270
R80
VMON9
J12
HEADER 3
1
2
3
GPIO3
TMON2P
J11
HEADER 2
1
2
SW3C
314
U1
ASC1012-48QFN
GND
49
GPIO6 1
HVOUT1 2
HVOUT2 3
WDAT
4
RDAT
5
WRCLK
6
ASCCLK
7
VCC 8
HVOUT3 9
HVOUT4 10
GPIO811
GPIO9 12
GPIO10 13
SDA
14
SCL
15
12C_ADDR
16
HIMONP
17
HIMONN_HVMON
18
IMON1P
19
IMPN1N
20
TMON1P
21
TMON1N
22
TMON2P
23
TMON2N
24
VMON1GS
25 VMON1
26
VMON2GS
27 VMON2
28
VMON3GS
29 VMON3
30
VMON4GS
31 VMON4
32
VCC 33
VMON5
34
VMON6
35
VMON7
36
VMON8
37
VMON9
38
TRIM1 39
TRIM2 40
TRIM3 41
TRIM4 42
RESETb43
GPIO1 44
GPIO2 45
GPIO3 46
GPIO4 47
GPIO5 48
R14 4.40K
TMON1N
TRIM1
GPIO4
SW3B
215
TMON2N
R15 2.20K
35
ASC Breakout Board
Figure 30. Trims DCDC 1-2 (Not Populated on Breakout Board)
5
5
4
4
3
3
2
2
1
1
DD
C C
BB
AA
GPIO9
3.3V @ 3A
5V @ 3A
GPIO8
TRIM1
TRIM2
VMON2
VMON1
Trims DCDC 1-2 (Not Populated)
5V @ 2A
3.3V @ 2A
SIP
Note: Components not populated
on breakout board
OUT_DCDC2
OUT_DCDC1
+12V_HS
+12V_HS
+3.3V
+3.3V
LED9
Sheet [2,8]
LED8Sheet [2,8]
TRIM_DCDC1
Sheet [2]
TRIM_DCDC2
Sheet [2]
VMON1 Sheet [2]
GS_VMON1 Sheet [2]
GS_VMON2 Sheet [2]
VMON2 Sheet [2]
+12V_HS
Sheet [2,7]
+3.3V
Sheet [2,4,5,6,7,8,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
113
Trims DCDC2-1 (Do Not Populate)
B
R92
470
J5
DCDC2
A
B
C
D
R26
open
RpupS
Q2
FDV301N
J4
DCDC1
A
B
C
D
R22
1K
R23
270
R30
open
RpdnD
R32
270
R90
470
R28
16.0k
Rs
R31
680
NQR002A0X4Z
DCDC1_A
DI
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
D22
Green
SM_LED_0603
R91
4.7k
C6
10uF
6.8V
OKY-T/3-D12P-C
DCDC2_B
DNI
GND
3
Vin
2
On-Off Control
1Trim 4
Vout5
R24
100
R29
open
RpupD
D21
Green
SM_LED_0603
Q1
FDV301N
R18
2.74k
RpdnS
R21
open
RpdnD
C8
10uF
6.8V
OKY-T/3-D12P-C
DCDC1_B
DNI
GND
3
Vin
2
On-Off Control
1Trim 4
Vout5
R89
4.7k
R16
10K
R20
open
RpupD
R25
10K
Q16
2N3904
C5
6.8uF
20V
R17
open
RpupS
R33
100
R19
11.0k
Rs
C7
6.8uF
20V
Q15
2N3904
R27
4.42k
RpdnS
NQR002A0X4Z
DCDC2_A
DI
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
SIP
ASC Breakout Board
36
ASC Breakout Board
Figure 31. Trims DCDC 3-4 (Not Populated on Breakout Board)
5
5
4
4
3
3
2
2
1
1
DD
C C
BB
AA
GPIO4
2.5V @ 3A
Trims DCDC 3-4 (Not Populated)
TRIM3
VMON3
1.2V @ 3A
GPIO5
VMON4
TRIM4
1.2V @ 2A
2.5V @ 2A
SIP
Note: Components not populated
on breakout board
OUT_DCDC3
OUT_DCDC4
+5V_HS
+5V_HS
+3.3V
+3.3V
LED4
Sheet [2,8]
TRIM_DCDC3Sheet [2]
LED5
Sheet [2,8]
TRIM_DCDC4Sheet [2]
VMON3 Sheet [2]
GS_VMON3 Sheet [2]
VMON4 Sheet [2]
GS_VMON4 Sheet [2]
+5V_HSSheet [2,6]
+3.3VSheet [2,3,5,6,7,8,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
114
Trims DCDC3-4 (Do Not Populate)
B
R38
open
RpdnD
R86
470
R47
330
R46
open
RpdnD
R85
4.7k
Q14
2N3904
C12
10uF
6.8V
R41
100
R39
470
R37
open
RpupD
R35
6.34k
RpdnS
R45
open
RpupD
R43
20.0k
RpdnS
R88
470
R49
100
Q13
2N3904
C9
6.8uF
20V
R42
open
RpupS
OKY-T/3-D12P-C
DCDC4_B
DNI
GND
3
Vin
2
On-Off Control
1Trim 4
Vout5
R44
39.0k
Rs
NQR002A0X4Z
DCDC3_A
DI
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
OKY-T/3-D12P-C
DCDC3_B
DNI
GND
3
Vin
2
On-Off Control
1Trim 4
Vout5
R34
open
RpupS
C10
10uF
6.8V
C11
6.8uF
20V
R36
22.0k
Rs
D20
Green
SM_LED_0603
D19
Green
SM_LED_0603
R87
4.7k
R40
270
NQR002A0X4Z
DCDC4_A
DI
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
J9
DCDC4
A
B
C
D
R48
270
J7
DCDC3
A
B
C
D
SIP
ASC Breakout Board
37
ASC Breakout Board
Figure 32. Inputs: Temperature Sensors, Trim Pots & Switches
5
5
4
4
3
3
2
2
1
1
DD
C C
BB
AA
Temperature Sensor 1
Temperature Sensor 2
Inputs: Temperature Sensors, Trim Pots & Switches
VMON7
VMON8
+3.3V
+3.3V
POT1 Sheet [2]
POT2 Sheet [2]
TEMP_SENSE1P Sheet [2]
TEMP_SENSE1NSheet [2]
TEMP_SENSE2P Sheet [2]
TEMP_SENSE2NSheet [2]
LED10 Sheet [2,8]
+3.3V
Sheet [2,3,4,6,7,8,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
115
Inputs: Temperature Sensors, Trim Pots, & Switches
B
B
Q4
2N3906
R51
1k
R50
1k
1
3
2
SW2
GPIO10
1 4
2 3
R53
1k
Q3
2N3906
R52
1k
1
3
2
ASC Breakout Board
38
ASC Breakout Board
Figure 33. Hot Swap, 5 V (Not Populated on Breakout Board)
5
5
4
4
3
3
2
2
1
1
DD
C C
BB
AA
Hot Swap, 5V (Not Populated)
IMON
VMON6
HVOUT2
Population Options:
Standard MOSFET (Option A):
Q6, C22, R61,
R60, R58, R59
MOSFET w/ Sense (Option B):
Q5, R57, R55,
C23, R54, R56
sense X 600
ASC INT
Connector
Fast
Shutdown
VMON5
I_5V_HS - 1V per 1A sensed
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
MOSFET w/ Sense (Option B)
Note: Components not populated
on breakout board
+5V_HS
+3.3V
+3.3V
5V_HS_DRIVE
Sheet [2]
+5V_HS Sheet [2,4]
5V_HS_CURRENT_P
Sheet [2]
5V_HS_CURRENT_N
Sheet [2]
ASC_5V_OC_SHUTDOWNSheet [2]
+5V_SWSheet [2,9,10]
+3.3VSheet [2,3,4,5,7,8,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
116
Hot Swap, 5V (Do Not Populate)
B
kelvin
sense
Q5
BUK7C06-40AITE
R58
0
TP7
5V_IN
1
R54
2.2k R60
0.005
2W, 1%
TP17
I_5V_HS
1
TP16
5V_SDN
1
R59
0
C22
100nF
R62
4.7k
R61
2.2k
R57
3.30
1%
R55
0
R64
1k
C23
100nF
D10
Red
SM_LED_0603
R94
20k
1%
TP12
5V_HS
1
Q6
IRF7832
J6
2 Position Terminal Block
A
B
Q7
2N3904
R63
3.3k
R56
0
C13
680uF
10V
U2
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
ASC Breakout Board
39
ASC Breakout Board
Figure 34. Hot Swap, 12 V (Not Populated on Breakout Board)
5
5
4
4
3
3
2
2
1
1
DD
C C
BB
AA
Hot Swap, 12V (Not Populated)
HIMON
ASC INT
Connector
VMON9
HVOUT1
sense X 600
I_12V_HS - 1V per 1A sensed
Population Options:
Standard MOSFET (Option A):
Q9, C20, R71,
R74, R75, C21
MOSFET w/ Sense (Option B):
Q11, R68, C26,
R69, R70, R67
Demonstration Circuit to Output
Monitored Current to Test Point
(Not required for Hot Swap Operation)
MOSFET w/ Sense (Option B)
Note: Components not populated
on breakout board
+12V_HS
PUMP_V
+12V_SW
+3.3V
+12V_SW
+3.3V
MON_12V_HS_CURRENT Sheet [2]
ASC_12V_OC_SHUTDOWNSheet [2]
CHARGE_PUMPSheet [2]
MON_12V_INSheet [2]
+12V_HS Sheet [2,3]
MON_12V_HS_VOLTAGE Sheet [2]
+12V_SWSheet [9,10]
+3.3VSheet [2,3,4,5,6,8,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
117
Hot Swap, 12V (Do Not Populate)
B
C16
10nF
R76
10k
R72
2.2k
R70
24
Q12
2N3904
R68
6.20
1%
R95
10k
1%
C17
10nF
C15
1000uF
25V
R77
10k
D12
Red
SM_LED_0603
Q9
IRF7832
C21
100nF
TP18
I_12V_HS
1
R71
2.2k
R65
3k
C18
100nF
C19
10nF
D13
1N4148
J8
2 Position Terminal Block
A
B
R67
2.2k
R74
24
TP14
12V_HS
1
C20
100nF
TP15
12V_SDN
1
R69
24
R79
1k
kelvin
sense
Q11
BUK7C06-40AITE
TP19
PUMP_V
1
R73
0.01
3W
1%
Q17
2N3906
Q10
IRF7832
D11
MMSZ5231BS-7-FL
5.1V
D14
MMSZ5240B-7-F
10V
R66
1.02k
TP13
12V_IN
1
U3
ZXCT1009
Vsense+
2
Vsense-
3
Iout
1
D15
1N4148
C26
100nF
R80
510k
R78
4.7M
R75
24
ASC Breakout Board
40
ASC Breakout Board
Figure 35. LEDs
5
5
4
4
3
3
2
2
1
1
DD
C C
B B
A A
LEDs
LED2 LED3 LED4 LED5 LED6 LED8LED9 LED10LED1
LED[1:10]
Sheet [2,3,4,5]
+3.3VSheet [2,3,4,5,6,7,9,10]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
11
8
LEDs
B
Schematic Rev
D1
Red
RN1A
2.2k
10
1
RN2B
2.2k
2
RN1C
2.2k
3
D4
Red
R82
2.2k
RN1G
2.2k
8
RN1F
2.2k
7
RN1E
2.2k
5
6
RN1H
2.2k
9
D2
Red
D6
Red
RN2A
2.2k
10
1
RN2D
2.2k
4
D7
Red
RN1B
2.2k
2
RN2E
2.2k
5
6
RN2F
2.2k
7
RN2C
2.2k
3
D8
Red
R81
2.2k
RN1D
2.2k
4
D3
Red
D5
Red
RN2H
2.2k
9
RN2G
2.2k
8
D9
Red
ASC Breakout Board
41
ASC Breakout Board
Figure 36. Board Power (Not Populated on Breakout Board)
5
5
4
4
3
3
2
2
1
1
DD
C C
B B
A A
Populate jumper to provide 3.3V power from ASC Eval Board
3.3V
1A
12V to 4.8V input range
Board Power (Not Populated)
Note: Components not populated
on breakout board
+11.3V
+3.3V
+12V
+5V
+11.3V
+11.3V
+3.3VSheet [2,3,4,5,6,7,8,10]+5V_SWSheet [2,6,10]
+12V_SWSheet [7,10]
+11.3VSheet [2]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
11
9
Board Power (Do Not Populate)
B
J14
HEADER 2
1
2
C31
100nF
25V
SW1
SW DPDT
2
3
5
6
1
4
J1
2 Position Terminal Block
A
B
J2
PWR JACK
3
2
1
J3
2 Position Terminal Block
A
B
R96
4.53K
C30
22uF
25V
D17
TRANZORB
C32
100nF
C29
22uF
25V
NQR002A0X4Z
DCDC5
GND
3
Vin
2
On-Off Control
1Trim 5
Vout4
D16
NSR0530P2T5G
D18
NSR0530P2T5G
ASC Breakout Board
42
ASC Breakout Board
Figure 37. Prototype and Mounting Holes
5
5
4
4
3
3
2
2
1
1
DD
C C
B B
A A
Prototype & Mounting Holes
SOT-23 Package Prototype Area SMD SOT-223 Prototype Area
SMD 2512 Resistor
Package Prototype Area
SOIC-8 Package Prototype Area
SMD 0805 Cs, Ds, or Rs Prototype Area
Board Logos
Board Mounting Holes
Through Hole Prototype Area
+12V_SWSheet [7]
+5V_SW
Sheet [2,6]
+3.3V
Sheet [2,3,4,5,6,7,8,9]
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
11
10
Prototype and Mounting Holes
ASC Breakout Board B
SheetSheet
MH3
M_HOLE1
DI
IW_MNT0
11
R104
1k
DNI
AF22
AF12
AH21
AJ15
AE18
AH11
AB13
AC20
AJ22
AF13
Q27
NDT3055LCT
DNI
AJ21
R105
1k
DNI
AJ16
AA11
MH1
M_HOLE1
DI
IW_MNT0
11
AG20
AB14
AD11
AG13
Q20
IRF7832
DNI
AJ17
AE19
AB15
AK21
AH12 AD12
MH4
M_HOLE1
DI
IW_MNT0
11
R106
1k
DNI
AH22
AE13
R111
1k
DNI
AJ18
AF20
AH13
AB16
Q22
2N3904
DNI
AD13
AK22
AE14
AJ19
AA12
AH14
AB17
AD14
Q21
IRF7832
DNI
R107
1k
DNI
MH2
M_HOLE1
DI
IW_MNT0
11
AG14
AK11
AA13
AB18
AH15 AD15
AF14
AJ20
AA14
Q23
2N3904
DNI
AH16
AB19
R112
1k
DNI
AD16
AG15
AK12
AA15
AB20
AD17
R113
1k
DNI
AH17
AE15
AK13
AA16
AC11
AD18AH18
AE16
Q24
2N3904
DNI
AK14
AA17
AC12
R108
1k
DNI
AD19
AA21
AE17
AK15
AA20
AC15
R100
1k
DNI
AA22
AD20
AB21
AF16
AH19
AA18
AK17
AC13
AB22
AG11
Q25
2N3904
DNI
AC21
AJ11
AF17
R101
1k
DNI
AK18
AA19
AC14
R109
1k
DNI
AC22
AD21
AF11
AH20
AF15
G1
Lattice Logo
1
AK16
AG17
AC16
R103
1k
DNI
AE22
AG12
AE21
AG16
AJ12
AE20
G3
E-Friendly
1
AC17
AD22
AE11
Q26
NDT3055LCT
DNI
AG21
R102
1k
DNI
AJ13
AF18AG18
AB11
AK19
AC18G2
WEEE
1
R110
1k
DNI
AG22
AF21
AE12
AJ14
AF19
AB12
AG19 AC19
AK20
43
ASC Breakout Board
Figure 38. Mechanical Drawing
5
5
4
4
3
3
2
2
1
1
DD
C C
B B
A A
Mechanical Drawing
Date:
Size Schematic Rev
of
Sheet
Title
Lattice Semiconductor Applications
Email: techsupport@Latticesemi.com
Board Rev
Project
Wednesday, April 30, 2014
BB
11
11
Mechanical Drawing
ASC Breakout Board B
Date:
44
ASC Breakout Board
Appendix B. Bill of Materials – Populated on Breakout Board
Quantity Reference
Designator Description Package Manufacturer Part Number
ICs
1 U1 ASC Device TQFN_48 Lattice
Semiconductor
L-ASC10-1SG48I
Capacitors
2 C1, C2 0.1uF 16 V 10% Ceramic X7R SMD 0603 Murata GRM188R71C104KA01D
2 C3, C4 150pF 50 V 5% Ceramic NP0 SMD 0603 Murata GRM1885C1H151JA01D
Diodes
9 D1, D2, D3, D4, D5,
D6, D7, D8, D9
Red LED SMD 0603 Lite-On Inc LTST-C190KRKT
Jumpers
1 J10 25-pin DSUB Connector TE Connectivity 5745783-4
1 J11 2 Pin Header Header_1x2 Molex Inc 22-28-4364
1 J12 3 Pin Header Header_1x3 Molex Inc 22-28-4364
Transistors
2 Q3,Q4 2N3906 PNP SOT23 Fairchild MMBT3906
Resistors
2 RN1, RN2 2.2 kΩ Resistor Network SMD 2512 CTS Resistor 745C101222JP
2 R1, R2 24 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ240V
1 R3 10 kΩ Resistor SMD 0603 Panasonic ERJ-3GEYJ103V
1R4 0 Ω Resistor SMD 0603 Panasonic ERJ-3GEY0R00V
2 R5, R6 270 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ271V
3 R9, R51, R53 1 kΩ Resistor SMD 0603 Panasonic ERJ-3GEYJ102V
1 R10 18.0 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF1802V
1 R11 14.0 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF1402V
1 R12 10.0 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF1002V
1 R13 7.00 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF7001V
1 R14 4.40 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF4401V
1 R15 2.20 kΩ Resistor 1%SMD 0603 Panasonic ERJ-3EKF2201V
2 R50, R52 1 kΩ Potentiometer TH_SLIDEPOT_4_25mm Alpha RA2043F-20-10EB1-B1K
2 R81, R82 2.2 kΩ Resistor SMD 0603 Panasonic ERJ-3GEYJ222V
Switches
1 SW2 Push Button Switch SMT_SW Panasonic EVQ-Q2K03W
1 SW3 8 Position Dip Switch 195_8MST CTS
Electrocomponents
195-8MST
45
ASC Breakout Board
Appendix C. Bill of Materials – Not Populated on Breakout Board
Quantity Reference
Designator Description Package Manufacturer Part Number
ICs
2 U2, U3 Current Sense Amplifier SOT23 Diodes Inc ZXCT1009FTA
Capacitors
8 C18, C201, C211,
C223, C234, C262,
C31, C32
0.1 uF 16 V 10% Ceramic X7R SMD 0603 Murata GRM188R71C104KA01D
4 C5, C7, C9, C11 6.8 uF 16 V 10% Tantalum SMD 1206 Kemet T491A685K016AT
4 C6, C8, C10, C12 10 uF 10 V 10% Tantalum SMD 1206 Kemet T491A106K010AT
1 C13 680 uF 10 V 20% Aluminum Radial Panasonic EEU-FM1A681L
1 C15 1000 uF 25 V 20% Aluminum Radial Panasonic EEU-FM1E102
3 C16, C17, C19 10 nF 50 V 10% Ceramic X7R SMD 0603 Kemet C0603C103K5RACTU
2 C29, C30 22 uF 25 V 20% Aluminum Radial Panasonic EEA-GA1E220H
DCDCs
5 DCDC1_A,
DCDC2_A,
DCDC3_A,
DCDC4_A, DCDC5
DC/DC Converter 0.6V-5.5 V 2A 5pin_SIP GE Critical Power NQR002A0X4Z
2 DCDC1_B,
DCDC2_B
DC/DC Converter 15W 12VIN
3AOUT
DOSA-SMT Murata Power OKY-T/3-D12P-C
2 DCDC3_B,
DCDC4_B
DC/DC Converter 10.9W 5VIN
3AOUT
DOSA-SMT Murata Power OKY-T/3-W5P-C
Diodes
2 D10, D12 Red LED SMD 0603 Lite-On Inc LTST-C190KRKT
1 D11 Zener Diode 5.1 V SM_SOD_323_12 Diodes Inc MMSZ5231BS-7-F
2 D13, D15 Diode 100 V 0.15 A SOD-123_12 Micro Commercial Co 1N4148W-TP
1 D14 Zener Diode 10 V SM_SOD_123 Diodes Inc MMSZ5240B-7-F
2 D16, D18 Schottky 30 V 500 mA SM_SOD_923 ON Semiconductor NSR0530P2T5G
1 D17 TVS Diode 22 V 600 W SM_SOD_214AA_12 Littlefuse SMBJ22CA
4 D19, D20, D21, D22 Green LED SMD 0603 Lite-On Inc LTST-C190KGKT
Jumpers
4 J1, J3, J6, J8 2 Position Terminal Block TERM_BLOCK_2POS Phoenix 1727010
1 J2 Pwr Jack PWR_JACK_PINS CUI Inc PJ-102AH
1 J4, J5, J7, J9 4 Position Terminal Block TERM_BLOCK_4POS Phoenix 1727036
1 J14 2 Pin Header Header_1x2 Molex Inc 22-28-4364
Transistors
2 Q1, Q2 N-Channel MOSFET 25 V SOT23 Fairchild FDV301N
2Q5
4, Q112N-Channel TrenchPLUS FET with
SENSE output
SOT427 NXP Semiconductor BUK7C06-40AITE
3Q6
3, Q91, Q10 N-Channel MOSFET 30 V SOIC8 International Rectifier IRF7832TRPBF
6 Q7, Q12, Q13, Q14,
Q15, Q16
2N3904 NPN SOT23 Fairchild MMBT3904
1 Q17 2N3906 PNP SOT23 Fairchild MMBT3906
Resistors
2R74
1, R75124 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ240V
4 R16, R25, R76, R77 10 kΩ Resistor SMD 0603 Panasonic ERJ-3GEYJ103V
4R7, R8, R58
3, R5930 Ω Resistor SMD 0603 Panasonic ERJ-3GEY0R00V
4 R23, R32, R40, R48 270 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ271V
3 R22, R64, R79 1 kΩ Resistor SMD 0603 Panasonic ERJ-3GEYJ102V
1 R27 4.42 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF4421V
1 R28 16.0 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF1602V
1 R31 680 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ681V
1 R35 6.34 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF6341V
1 R36 22.0 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF2202V
46
ASC Breakout Board
1 R39, R86, R88, R90,
R92
470 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ471V
5 R43 20.0 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF2002V
1 R44 39.0 kΩ Resistor SMD 0603 Panasonic ERJ-3EKF3902V
1 R47 330 Ω Resistor SMD 0603 Panasonic ERJ-3GEYJ331V
2R54
4,R6722.2 k SMD 0603 Panasonic ERJ-3GEYJ222V
2R55
4,R5640 SMD 0603 Panasonic ERJ-3GEY0R00V
1R57
43.3 SMD 1206 Vishay-Dale CRCW12063R30FKEA
1R60
30.005 SMD 2512 Rohm Semi PMR100HZPFU5L00
1 R62 4.7 k SMD 0603 Panasonic ERJ-3GEYJ472V
1 R63 3.3 k SMD 0603 Panasonic ERJ-3GEYJ332V
1 R65 3 k SMD 0603 Panasonic ERJ-3GEYJ302V
1 R66 1.02 k SMD 0603 Panasonic ERJ-3EKF1021V
1R68
26.2 SMD 1206 Vishay-Dale CRCW12066R20FKEA
2R69
2, R70224 SMD 0603 Panasonic ERJ-3GEYJ240V
3R71
1, R72, R6132.2 k SMD 0603 Panasonic ERJ-3GEYJ222V
1 R73 0.01 SMD 2512 Bourns CRA2512-FZ-R010ELF
1 R95 10 k SMD 0603 Panasonic ERJ-3EKF1002V
1 R78 4.7 M SMD 0603 Panasonic ERJ-3GEYJ475V
1 R80 510 k SMD 0603 Panasonic ERJ-3GEYJ514V
4 R85, R87, R89, R91 4.7 k SMD 0603 Panasonic ERJ-3GEYJ472V
1 R94 20 k SMD 0603 Panasonic ERJ-3EKF2002V
1 R96 4.53 k SMD 0603 Panasonic ERJ-3EKF4531V
Switches
1 SW1 DPDT Power Switch SW DPDT NKK Switches M2022SS1W03_RO
1. Only populate for 12 V Standard MOSFET Hot Swap. Populate only from either Note 1 or Note 2, never both.
2. Only populate for 12 V MOSFET with Sense Output Hot Swap. Populate only from either Note 1 or Note 2, never both.
3. Only populate for 5 V Standard MOSFET Hot Swap. Populate only from either Note 3 or Note 4, never both.
4. Only populate for 12 V MOSFET with Sense Output Hot Swap. Populate only from either Note 3 or Note 4, never both.
47
ASC Breakout Board
Appendix D. Known Issues
The populated components on the breakout board work as specified without issue. There is an issue related to the
footprints and connections in the 12 V Hot Swap – Charge Pump section of the board.
The footprint for Q17 contains an error in the connection to the device pins. Figure 39 shows the footprint of Q17,
with each of the device pin connections labeled. The footprint has the base and collector pin connections swapped.
Q17 needs to be populated according to Figure 40, with the connections swapped, in order for the 12 V Hot Swap
circuit to function properly.
Figure 39. 12 V Hot Swap - Charge Pump - Q17 Footprint Error
Figure 40. 12 V Hot Swap - Charge Pump - Q17 Correction
One method for fixing the connection on the board is to place Q17 (2N3906) in the configuration shown in
Figure 41. In this configuration, Q17 is flipped upside down, and then rotated clockwise. This configuration results
in the collector and base connections being swapped back to the correct pin connections.
Emitter
Base*
Collector*
* - Incorrect
Connections
Emitter
Base
Collector
Swap Connection
48
ASC Breakout Board
Figure 41. Q17 - Orientation for Corrected Connection
