FUSB3307D45A0AFMNWTWG [ONSEMI]
USB Power Delivery 3.0 Adaptive Source Charging Controller;型号: | FUSB3307D45A0AFMNWTWG |
厂家: | ONSEMI |
描述: | USB Power Delivery 3.0 Adaptive Source Charging Controller |
文件: | 总21页 (文件大小:616K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
USB Power Delivery 3.0
Adaptive Source Charging
Controller
FUSB3307
FUSB3307 is a highly integrated USB Power Delivery (PD) power
source controller that can control a DC−DC port power regulator or the
opto−coupler in the secondary side of an AC−DC adapter. It
implements the Source finite state machines of USB Power Delivery
3.0 (PD 3.0) and Type−C™ which includes Programmable Power
Supplies (PPS). In order to meet the PPS specification, FUSB3307
supports minimum 3.3 V and maximum 21 V output voltage control.
It includes Constant Voltage (CV) and Constant Current Limit (CL)
control blocks. The references are supported from internal D/A
converters.
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14
1
SOIC−14 NB
CASE 751A−03
QFNW20 4x4, 0.5P
CASE 484AT
(In Development)
FUSB3307 supports various protections, Under Voltage Protection
(UVP), Over Voltage Protection(OVP), Over Current Protection
(OCP), CC1 and CC2 Over Voltage Protection (CC_OVP), VCONN
Over Current Protection (VCONN_OCP), and internal and external
Over Temperature protection (I_OTP and E_OTP). With a 10−bit A/D
converter, output voltage, output current, IC internal temperature and
external temperature via an NTC resistor can be monitored.
FUSB3307 is capable of controlling a single or back−to−back
N−Channel MOSFETs as a load switch, which results in a lower cost
and easier design.
GENERIC MARKING DIAGRAMS
14
3307
FUSB3307D6MX
AWLYWW
D6x
ALYWG
G
1
FUSB3307D6MX = Specific Device Code
= Assembly Location
WL, L = Wafer Lot
= Year
WW, W = Work Week
A
Y
Features
G
= Pb−Free Package
• PD 3.0 v2.0 and Type−C 2.0 Compliant
(Note: Microdot may be in either location)
• Constant Voltage (CV) and Constant Current Limit (CL) Regulation
• Small Current Sensing Resistor (5 mW) for High Efficiency
• Gate Driver for N−Channel MOSFET as a Load Switch
• CC1/CC2 Pin Protection up to 26 V
PIN DESCRIPTION
See detailed pin description information on page 5 of this
data sheet.
• Selectable Resistor Divider or Battery Charging (BC1.2) Modes
• Built−in Output Capacitor Discharging Resistance
• Adaptive UVP, Adaptive OVP, I_OTP, E_OTP, CC_OVP and
VCONN_OCP Fault Detection
ORDERING INFORMATION
See detailed ordering and shipping information on page 5 of
this data sheet.
• 14−pin SOIC and 20−pin QFN Packages Available
Applications
• Wall Chargers for Tablet PC’s and Laptop Batteries
• AC−DC PD 3.0 Compliant Adapters
• DC−DC Car Chargers for Individual Port Power Control
This document contains information on some products that are still under development.
ON Semiconductor reserves the right to change or discontinue these products without
notice.
© Semiconductor Components Industries, LLC, 2018
1
Publication Order Number:
July, 2020 − Rev. 0
FUSB3307/D
FUSB3307
APPLICATION DIAGRAM
Figure 1. Offline Application Diagram
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2
FUSB3307
Figure 2. Automotive Application Diagram
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3
FUSB3307
VDD
VCC GATE DISC
D+/PDIV1 D−/PDIV0
vdd
PDIV1
PDIV0
GND
Resistor
Divider / BC 1.2
Option
Gate Driver
vdd
vdd
9R
R
V
V
/
IN−ON
Discharge
FAULT
IN−OFF
CC1
CC2
V
CS−AMP
Trigger
_BLD
RESET
Protection
vdd
CC State Machine &
Comparators
vdd
1.1V REG
IFB
IS+
X A
VCCR
R c v r
B M C
V
CS−AMP
Policy
Engine
IS−
VCCR
vdd
BMC
Cable Drop
Compensation
Option
DRIVER
(+Timers)
Protection
PDIV0
CRC32
Tx
VFB
V
COMR
BMC
S
4B5B
4B5B
FAULT
Encode
CDR
Device
Protocol
VCVR
Protection
Block
Policy
(+Timers)
PDIV1
Manager
OVP/UVP/
OCP
BMC
(DPM)
Decode
V
PDIV2
IN−1:10
State
Machine
CRC32
Rx
V
vdd
V
COMR
FAULT
CS−AMP
Protection
V
V
CS−AMP
Band
Gap
Analog to Digital
Converter
NTC
LF
Osc.
IN−1:10
PD
Trim
Osc.
Internal temp.
CATH
Figure 3. Block Diagram
VCC
GND
GATE
VDD
1
2
3
4
5
6
7
14 CATH
20 19 18 17 16
DISC
IFB
13
12
11
10
9
1
2
3
4
5
N/C
D−/PDIV0
CC1
15
GND
VCC
N/C
FUSB3307
QFN
14
13
FUSB3307
SOIC
VFB
GND
IS−
D+/PDIV1
D−/PDIV0
CC1
GND
12 CATH
Top View
CC2
11
DISC
IS+
CC2
10
6
7
8
9
8
Top View
14
13
12
11
10
9
1
2
3
4
5
6
7
VCC
CATH
DISC
IFB
16 17 18 19 20
GND
1
2
3
4
5
15
14
13
N/C
GND
VCC
N/C
FUSB3307
QFN
GATE
VDD
D−/PDIV0
FUSB3307
SOIC
VFB
IS−
CC1
GND
CC2
GND
D+/PDIV1
CATH 12
11
Bottom View
DISC
IS+
D−/PDIV0
10
9
8
7
6
CC1
8
CC2
Bottom View
Figure 4. Pin Diagrams
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FUSB3307
PIN FUNCTION DESCRIPTION
SOIC Pin
Number
QFN Pin
Number
Pin Name
I/O Type
Description
1
14
VCC
Supply
Output voltage (Input voltage to the FUSB3307). This pin is tied to the output of
the power source to monitor its output voltage and supply internal bias to the
FUSB3307 via the VDD pin.
4
2
19
VDD
GND
CATH
Supply
Ground
Internal supply voltage regulator output. This pin should be connected to an 1 mF
external capacitor
4, 15,
DAP
Ground
14
12
Open Drain Feedback to control the power supply. Typically an opto−coupler cathode on the
Output
secondary side is connected to this pin to provide feedback signal to the primary
side PWM controller. Alternatively, this can be connected to the error amplifier
output of a DC−DC regulator (often called the compensation pin) or with an invert-
ing circuit to the DC−DC feedback (FB) pin.
11
12
8
9
VFB
IFB
Input
Output Voltage Sensing Signal. This pin is used for constant voltage (CV) regula-
tion, and it is tied to the internal CV loop amplifier non−inverting input terminal. It
is tied to the output voltage external 1:10 resistor divider and a compensation
circuit
Input
Constant Current Amplifying Signal. The voltage level at this pin is the amplified
current sense signal used for providing an external compensation circuit. Internal-
ly this pin is tied to the non−inverting input of the current loop error amplifier.
10
9
7
6
IS−
Input
Input
Current sensing amplifier negative terminal. Connect this pin directly to the nega-
tive end of the current sense resistor with a short PCB trace
IS+
Current sensing amplifier positive terminal. Connect this pin directly to the posi-
tive end of the current sense resistor with a short PCB trace
3
17
11
GATE
DISC
Output
Gate drive signal to drive the gate of an NFET load switch
13
Open Drain Discharge pin. This pin should be tied to a small (40 W) external resistor that is
I/O
connected to VBUS after the load switch to discharge VBUS at the connector
7
8
5
3
5
CC1
CC2
I/O
Configuration Channel 1. This pin is used to detect USB Type−C devices and
communicate over USB PD
I/O
Configuration Channel 2. This pin is used to detect USB Type−C devices and
communicate over USB PD
20
D+/PDIV1
D+: I/O
Different functionality available with Trim option (see Application Information
PDIV1: Input section and note at the bottom of Table 6 below):
D+: Connected to D+ for BC1.2 or resistor divider mode
PDIV1: Programmable pin to select different USB Power Delivery Power (PDP)
values
6
2
D−/PDIV0
D−: I/O
Different functionality available upon request:
PDIV0: Input D−: Connected to D− for BC1.2 or resistor divider mode
PDIV0: Programmable pin to select different USB Power Delivery Power (PDP)
values
N/A
N/A
10
16
PDIV2
NTC
Input
I/O
Programmable pin to select different USB Power Delivery Power (PDP) values
Pin connected to external NTC resistor to sense PCB or connector temperature
ORDERING INFORMATION
Part Number
Top Mark
Operating Temperature Range
Package
Packing Method
FUSB3307D6MX
FUSB3307D6MX
−40°C to 85°C
SOIC−14 NB
(Pb−Free)
Tape and Reel
FUSB3307D6VMNWTWG
(In Development)
3307
D6V
−40°C to 105°C
−40°C to 85°C
QFNW20
(Pb−Free)
Tape and Reel
Tape and Reel
FUSB3307D6MNWTWG
(In Development)
3307
D6
QFNW20
(Pb−Free)
Other trim (see note at the
bottom of Table 6) or
package options
Please contact
ON Semiconductor sales
−
−
−
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FUSB3307
Table 1. MAXIMUM RATINGS (Notes 1, 2)
Rating
Symbol
Value
−0.3 to 26
−0.3 to 30
−0.3 to 6
−0.3 to 6
1.5
Unit
V
VCC, CATH, DISC, CC1, CC2 Pin Voltage
GATE Pin Voltage
V
CC
V
GATE
V
IFB, VFB, IS+, IS−, NTC, D+/PDIV1, D−/PDIV0, PDIV2 Pin Voltage
V
V
I/O
DD
VDD Pin Voltage
V
V
Power Dissipation (T = 25°C)
P
D
W
°C
°C
°C
kV
kV
A
Operating Junction Temperature
T
J
−40 to 150
−40 to 150
260
Storage Temperature Range
T
STG
Lead Temperature, (Soldering, 10 Seconds)
Human Body Model, ANSI/ESDA/JEDEC JS−001−2012 (Note 3)
Charged Device Model, JESD22−C101 (Note 3)
TL
ESD
2
HBM
CDM
ESD
0.5
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
1. All voltage values, except differential voltages, are given with respect to the GND pin.
2. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.
3. Meets JEDEC standards JS−001−2012 and JESD 22−C101.
Table 2. THERMAL CHARACTERISTICS (Note 4)
Rating
Symbol
Value
Unit
R
Thermal Characteristics,
Thermal Resistance, Junction−to−Air, SOIC14
Thermal Reference, Junction−to−Top, SOIC14
Thermal Resistance, Junction−to−Air, QFNW20
Thermal Reference, Junction−to−Top, QFNW20
75
q
JA
JT
JA
JT
R
41.6
36.1
2.3
q
°C/W
R
R
q
q
4. T =25°C unless otherwise specified with JEDEC 2S2P board with no thermal vias.
A
Table 3. RECOMMENDED OPERATING RANGES
Rating
Symbol
Min
Max
Unit
V
Input Voltage
V
CC
3.3 − 5%
21 + 5%
5
Output Current Through Load Switch
Adjustable Type−C Connector VBUS Output Voltage
Ambient Temperature
I
A
OUT
VBUS
3.3 − 5%
−40
21 + 5%
V
T
A
85 (Commercial)
105 (Automotive)
°C
Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond
the Recommended Operating Ranges limits may affect device reliability.
Table 4. ELECTRICAL CHARACTERISTICS V = 5 V, T = −40°C to 125°C unless otherwise specified.
CC
J
Parameter
Test Conditions
Symbol
Min
Typ
Max
Unit
VDD SECTION
VDD Operating Voltage at VCC = 20 V
VDD Source Current
V
V
= 20 V, I
= 0 mA
V
4.75
10
5.2
5.5
V
CC
VDD
DD
= 3.3 V, V = 2.9 V
I
mA
CC
DD
DD
VCC SECTION
Continuous Operating Voltage (Note 5)
Operating Supply Current at 5 V
V
21 + 5%
V
CC−OP
V
= 5 V, sense resistor voltage dif-
I
2.4
mA
CC
CC−OP−5V
ference (V ) = 25 mV, sense resistor
CS
(R ) = 5 mW
CS
Operating Supply Current at 20 V
Turn−On Threshold Voltage
Turn−Off Threshold Voltage
Turn−Off to Turn−On Hysteresis
V
CC
V
CC
V
CC
V
CC
= 20 V, V = 25 mV, Rcs = 5 mW
I
CC−OP−20V
3.1
3.2
mA
V
CS
increasing
V
2.9
2.80
100
3.4
3.10
360
CC−ON
decreasing after V w V
V
2.87
260
V
CC
CC−ON
CC−OFF
CC−OFF_HYS
V
decreasing after V w V
mV
CC
CC−ON
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FUSB3307
Table 4. ELECTRICAL CHARACTERISTICS V = 5 V, T = −40°C to 125°C unless otherwise specified.
CC
J
Parameter
Test Conditions
Symbol
Min
Typ
Max
Unit
VCC SECTION
Standby Operating Supply Current
V
= 5 V, V = 0 mV (I
P−CC2−330
I
0.85
1.1
mA
CC
CS
P−CC1−330
CC−STBY
and I
not flowing since CC1
and CC2 are HIGH)
VCC−UVP SECTION
Ratio V Under−Voltage−Protection (UVP)
V
CS
= 0 mV
K
CC−UVP
60
65
70
%
CC
to V
CC
UVP Debounce Time
t
45
60
75
ms
ms
D−UVP
UVP Blanking Time during a Voltage Tran- Whenever a voltage change occurs
sition
t
160
200
240
BNK−UVP
from lower VBUS to a higher VBUS
VCC−OVP SECTION
Ratio V Over−Voltage−Protection (OVP)
V
CS
= 0 mV
K
CC- OVP
116.0
121
127.0
%
CC
to V
CC
V
V
Maximum Over−Voltage−Protection
23
35
23.8
75
7
24.8
110
V
CC−OVP−MAX
CC
OVP Debounce Time
t
ms
ms
D−OVP
OVP Blanking Time during a Voltage Tran- VBUS voltage transition step (V
sition (Note 5)
)
t
t
t
t
STEP
BNK−OVP1
BNK−OVP2
BNK−OVP3
BNK−OVP4
v 0.5 V, Final VBUS > 13 V
OVP Blanking Time during a Voltage Tran-
sition (Note 5)
V
STEP
V
STEP
V
STEP
v 0.5 V, Final VBUS < 13 V
19
56
ms
ms
ms
OVP Blanking Time during a Voltage Tran-
sition (Note 5)
> 0.5 V, Final VBUS > 13 V
> 0.5 V, Final VBUS < 13 V
OVP Blanking Time during a Voltage Tran-
sition (Note 5)
221
CONSTANT CURRENT LIMIT SENSING SECTION (100% Constant Current)
Current−Sense Amplifier Gain (Note 5)
R
= 5 mW
A
40
V/V
A
CS
V−CCR
Current threshold on sensing resistor be-
Constant Current Limit mode and
V = 5 V, 20 V
CC
I
I
I
I
I
0.85
1.85
2.85
3.80
4.75
48
1.00
1.15
2.15
3.15
4.20
5.25
52
CS−1A
CS−2A
CS−3A
CS−4A
CS−5A
tween IS+ and IS− at I
= 1.00 A
OUT
Current threshold on sensing resistor be-
tween IS+ and IS− at I = 2.00 A
Constant Current Limit mode and
= 5 V, 20 V
2.00
3.00
4.00
5.00
50
A
A
V
CC
OUT
Current threshold on sensing resistor be-
tween IS+ and IS− at I = 3.00 A
Constant Current Limit mode and
= 5 V, 20 V
V
CC
OUT
Current threshold on sensing resistor be-
tween IS+ and IS− at I = 4.00 A
Constant Current Limit mode and
= 5 V, 20 V
A
V
CC
OUT
Current threshold on sensing resistor be-
tween IS+ and IS− at I = 5.00 A
Constant Current Limit mode and
= 5 V, 20 V
A
V
CC
OUT
Current threshold on sensing resistor be-
tween IS+ and IS− at DI = 50 mA
Constant Current Limit mode and
= 5 V
I
mA
CS−STEP
V
CC
OUT
OVER CURRENT PROTECTION SENSING SECTION
Over Current Protection (OCP) threshold on Constant Voltage mode, PD Request
I
I
3.42
5.7
50
3.60
6.0
3.78
6.3
70
A
A
CS−3A
sensing resistor between IS+ and IS− Message = 3 A and V = 5 V
CC
Over Current Protection (OCP) threshold on Constant Voltage mode, PD Request
CS−5A
sensing resistor between IS+ and IS−
Message = 5 A and V = 5 V
CC
OCP Debounce Time
t
60
ms
OCP−DEB
Current threshold on sensing resistor be-
tween IS+ and IS− for enabling discharge
on DISC pin during a voltage transition
VBUS is decreasing
I
330
mA
CS−EN−DSCG
Debounce time for enabling discharge on
DISC pin during a voltage transition
t
0.6
1.0
ms
V
CS−EN−DSCG
CONSTANT VOLTAGE SENSING SECTION
VFB Reference Voltage at 3.3 V
V
CC
= 3.3 V, V = 0 V
V
CVR−3.3V
0.320
0.330
0.340
CS
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FUSB3307
Table 4. ELECTRICAL CHARACTERISTICS V = 5 V, T = −40°C to 125°C unless otherwise specified.
CC
J
Parameter
Test Conditions
Symbol
Min
Typ
Max
Unit
CONSTANT VOLTAGE SENSING SECTION
VFB Reference Voltage at 5.0 V
(Power−on reset, default)
V
CC
= 5.0 V, V = 0 V
V
CVR−5.0V
0.485
0.500
0.515
V
CS
VFB Reference Voltage at 9 V
VFB Reference Voltage at 12 V
VFB Reference Voltage at 15 V
VFB Reference Voltage at 20 V
VFB Reference Voltage of 20 mV step
FEEDBACK SECTION
V
V
V
V
= 9 V, V = 0 V
V
0.873
1.164
1.455
1.940
1.940
0.900
1.200
1.500
2.000
2.000
0.927
1.236
1.545
2.060
2.060
V
V
CC
CC
CC
CC
CS
CVR−9V
CVR−12V
CVR−15V
CVR−20V
= 12 V, V = 0 V
V
V
V
CS
= 15 V, V = 0 V
V
CS
= 20 V, V = 0 V
V
CS
V
CVR−STEP−20mV
DV = 20 mV, V = 0 V
mV
CC
CS
CATH Pin Sink Current (Note 5)
Minimum guaranteed sink current ex-
pected from CATH pin
I
2
mA
CATH−Sink
DISCHARGE SECTION
VBUS to GND leakage resistance when
VBUS is not being sourced
GATE = 0 V
R
72.4
170
250
155
kW
mA
mA
DISC−BUS
I
VCC −Sink
VCC Pin Sink Current when discharging
(Note 5)
Discharging current on VCC after a
fault has triggered at VCC = 20 V
DISC Pin Sink Current when discharging
(Note 5)
Discharging current on DISC during a
voltage transition at VCC = 20 V,
I
DISC −Sink
I
< I
OUT
CS−EN−DSCG
Discharge Time (Note 5)
VBUS voltage transition step (V
)
t
7
ms
STEP
DISC1
v 0.5 V, Final VBUS > 13 V,
I
< I
CS−EN−DSCG
OUT
Discharge Time (Note 5)
Discharge Time (Note 5)
Discharge Time (Note 5)
V
v 0.5 V, Final VBUS < 13 V,
< I
CS−EN−DSCG
t
t
t
19
56
ms
ms
ms
STEP
OUT
DISC2
DISC3
DISC4
I
V
> 0.5 V, Final VBUS > 13 V,
STEP
OUT
I
< I
CS−EN−DSCG
V
> 0.5 V, Final VBUS < 13 V,
221
STEP
OUT
I
< I
CS−EN−DSCG
OVER TEMPERATURE PROTECTION SECTION
Current Source on NTC pin (Note 6)
Resistance to ground on NTC =
3.293 kW
I
55
60
90
65
mA
ms
°C
°C
NTC
Debounce time for External Over Tempera-
ture Protection (E_OTP) (Note 6)
t
NTC−DEB
Internal Die Warning Temperature Thresh-
old (Note 5)
T
125
135
I_WARN
Internal Die Over−Temperature Threshold
(Note 5)
T
I_OTP
PROTECTION RECOVERY SECTION
VCC Voltage Release Threshold
UVP fault causing release when VCC
< V
V
V
LATCH
0.9
1.8
LATCH
Duration for Disabling Load Switch When
Fault Removed in Normal Mode (Note 5)
After fault OVP, UVP, OCP, E_OTP,
I_OTP or CC_OVP has recovered
t
t
2
2.2
0.4
sec
ms
2S_AR_NM
2S_SR_DM
Duration for Disabling Load Switch When
Fault Removed in Debug Test Mode
100
INPUTS SECTION
PDIV2, PDIV1 and PDIV0 input LOW volt-
age
Input LOW
V
V
V
V
IL
V
− 0.4
PDIV2, PDIV1 and PDIV0 input HIGH volt- Input HIGH
age
DD
IH
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FUSB3307
Table 4. ELECTRICAL CHARACTERISTICS V = 5 V, T = −40°C to 125°C unless otherwise specified.
CC
J
Parameter
TYPE C SECTION
Test Conditions
Symbol
Min
Typ
Max
Unit
330 mA Source Current on CC1 Pin
180 mA Source Current on CC1 Pin
V
= 5 V, V
= 0 V
I
I
304
166
330
180
356
194
mA
mA
CC
CC1
P−CC1−330
Used for USB PD to signal that the
Sink can communicate, V = 5 V,
P−CC1−180
CC
V
CC1
= 0 V
330 mA Source Current on CC2 Pin
180 mA source current on CC2 Pin
V
= 5 V, V
= 0 V
I
I
304
166
330
180
356
194
mA
mA
CC
CC2
P−CC2−330
Used for USB PD to signal that the
Sink can communicate, V = 5 V,
P−CC2−180
CC
V
V
V
= 0 V
CC2
Input Impedance on CC1 Pin
Input Impedance on CC2 Pin
= 0 V, Sourcing 330 mA on CC1
= 0 V, Sourcing 330 mA on CC2
Z
Z
126
126
0.75
kW
kW
V
CC
CC
CC
OPEN−CC1
OPEN−CC2
Ra Impedance Detection Voltage Threshold
on CC1 Pin
V
V
= 5 V, V
= 5 V, Decreasing
= 5 V, Decreasing
= 5 V,
V
V
V
V
0.80
0.80
2.60
2.60
150
0.85
0.85
2.75
2.75
200
CC2
CC1
CC2
RA−CC1
RA−CC2
RD−CC1
RD−CC2
CC1
Ra Impedance Detection Voltage Threshold
on CC2 Pin
V
V
= 5 V, V
0.75
2.45
2.45
V
V
V
CC
CC2
Rd Impedance Detection Voltage Threshold
on CC1 Pin
V
CC
= 5 V, V
Decreasing V
CC1
Rd Impedance Detection Voltage Threshold
on CC2 Pin
V
CC
= 5 V, V
= 5 V,
CC2
CC1
Decreasing V
Sink Attach Debounce Time (Note 5)
GATE High Voltage at 3.3 V
GATE High Voltage at 21 V
V
CC
V
CC
V
CC
V
CC
= 5 V
t
100
5.3
ms
V
CCDebounce
= 3.3 V
= 21 V
V
GATE−3.3V
V
24.5
V
GATE-21V
GATE High Voltage at V
= V
V
30
V
IN−OVP−MAX
CC−OVP−MAX
GATE−MAX
V
V
V
V
supply voltage
OCP voltage
V
3.0
50
5.5
V
CONN
CONN
CONN
CONN
CONN
CONN_OCP
I
mA
ms
mA
V
OCP debounce time
supply current
t
2.6
34
3.6
4.7
VCONN_OCP
V
= 4.75 V, VCONN = 3 V
IV
CONN
CC
CC1 Pin Over−Voltage Protection
CC2 Pin Over−Voltage Protection
CC1/CC2 OVP Debounce Time
Safe Operating Voltage at 0 V
USB PD BMC TRANSMITTER SECTION
Unit internal
V
5.5
5.5
5.75
5.75
28
6.0
6.0
CC1−OVP
CC2−OVP
V
V
t
ms
V
-
CC OVP−DEB
VSafe0V
0.66
0.73
0.80
1/fBitRate
tUI
3.03
1.05
3.70
1.2
ms
V
Logic High Voltage
IOH = −165 mA or 293 mA
IOL = 763 mA
V
1.125
OH
Logic Low Voltage
V
0.075
700
700
75
V
OL
Rise−TX
Rise time
VDD = 4.7 mF
t
300
300
33
500
500
ns
ns
W
Fall time
VDD = 4.7 mF
t
Fall−TX
Transmitter output impedance
USB PD BMC RECEIVER SECTION
Rx bandwidth limiting filter
CC receiver capacitance
Receiver Input Impedance
zDriver
t
100
1
ns
pF
RxFilter
cReceiver
zBmcRx
15
MW
Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product
performance may not be indicated by the Electrical Characteristics if operated under different conditions.
5. Guaranteed by Design
6. QFN package only where NTC pin is available
www.onsemi.com
9
FUSB3307
Application Information
FUSB3307 has the entire PD Device Policy Manager
where the FUSB3307 directly controls the DC/DC
controller. In the descriptions that follow, both of these
designs are discussed when describing the operation of the
FUSB3307. Interspersed within these descriptions is how it
relates to USB Power Delivery (PD) and Type C
specifications. These are just two example designs since
there are considerably more use cases of the FUSB3307 in
reference designs for power source applications. For more
information on specific design needs, please contact your
ON Semiconductor field application engineers.
(DPM), PD Policy Engine, Protocol and PHY layers within
hardware and it responds to all the messages typical for PD
Power Sources. No external processor is needed and it is
completely USB PD 3.0 with PPS compliant.
Two Reference Design Examples
Below are two reference design example applications of
the FUSB3307. One is an AC/DC design on the secondary
side of the offline design and the other is a DC/DC design
FDMC012N03
VCC
Q1
ESD
7272
C8
GATE
C1
R4
C4
USB Type−C
Detection
and Gate
Drivers
VCC
R5
VBUS
DISC
CC2
R1
C9
Sync. Rec.
Ctrl (e.g.
IS+
PD 3.0
Device Policy
Manager,
Policy
NCP430x)
D−/PDIV0
D+/PDIV1 R3
R2
IS−
R10
PWM Controller
(e.g. NCP1345,
NCP12601)
CC1
C2
R11
Engine,
CATH
IFB
C10
VDD
Protocol &
PHY Layers
C3
R6
C5
R8
ESD
7272
ESD
7272
C6
CV/CC
C7
Regulation
R7
26V
VFB
2 ESDM3551’s
FUSB3307
R9
Figure 5. Offline Reference Design Example
CSN1
CSP2 CSN2
CSP1
NVMFS5A140PLZ
VSW1
VSW2
HSG2
NVTFS4C10N
HSG1
SZ1SMB
30CAT3G
C8
26V
NVTFS4C10N
SZMM3Z
18VT1G
NVTFS002N04CL
VCC599
LSG1
LSG2
2 x
NVTFS4C10N
NVTFS4C10N
NSVR
0240
V2
Q1
SZESD
7272
BST1
BST2
V1
HSG1
LSG1
HSG2
LSG2
HSG1
LSG1
HSG2
LSG2
VCC599
VCCD
VDRV
VCC
GATE
VCC
VBUS
NCV81599
DISC
CC2
EN
R1
USB Type−
PGND1
VCC599
5V
VSW1
VSW2
VSW1
VSW2
C
PGND2
CSP1
CSN1
CSP2
CSN2
FB
R4
R5
Detection
and Gate
Drivers
CSP1
CSN1
CSP2
CSN2
D−_HOST
D−/
PDIV0
D+/
D−
PDRV
D+_HOST
NIV1241
D+
PDIV1
IS+
GND
SDA
C4
PD3.0
Device
Policy
CC1
SCL
CLIND
ADDR
IS−
CS1
CS2
Manager,
Policy
COMP
AGND GND
C1
SZESD
7272
Engine,
Protocol&
PHY
SZESD
C2
CATH
IFB
7272
Layers
R6
C5
R12
VDD3307
C6
CV/CC
Regulation
PDIV2
OTP
C7
R14
R16
R15
R8
R7
FUSB3307
VDD3307
C3
NTC
R13
VDD
VFB
GND
R9
Figure 6. Automotive DC/DC Reference Design Example
www.onsemi.com
10
FUSB3307
Power Up and Assumptions
typical default operation. However this buck−boost resistor
divider is set to 1:50 ratio to set the upper limit of the voltage
while the FUSB3307 directly controls the PWM operation
within the buck−boost. If direct COMP pin control of the
buck−boost is not desirable, then the FUSB3307 can control
the FB pin via a simple external circuit. Please contact
ON Semiconductor Field Application Engineers for more
details.
FUSB3307 will not attach to any Sink devices unless 5 V
(4.75 V to 5.5 V voltage range) is first attained on its VCC
pin since that is the basis of both the USB Type C and USB
Power Delivery (PD) specifications. From this 5 V on VCC,
the FUSB3307 derives its VDD voltage which is used for
powering the internal circuitry as illustrated by this section
of the block diagram shown in Figure 8.
For Figure 5, the focus is on only the secondary side of this
power source and only on the interactions with the
FUSB3307 device. For Figure 6, only the interconnections of
the FUSB3307 with the buck−boost shown will be discussed,
not the buck−boost operation. It is assumed all other
functionality of these AC/DC and DC/DC designs is known.
For Figure 5, upon application of an AC source, the
secondary side VCC starts at 5 V and for Figure 6, upon
application of input VBAT, the buck−boost regulates VCC
at 5 V for USB−C operation. The FUSB3307 takes its input
from the resistor divider ratio comprising of R8 and R9 in
Figure 5 and Figure 6 above. In Figure 5, FUSB3307
controls the CATH pin current through the opto−coupler,
R11 and R10 resistors for providing the feedback to the
primary side controller to regulate to 5 V as shown in
Figure 7.
Figure 7. Constant Voltage / Constant Current
(CV/CC) section of Application Diagram
Figure 8. VDD Generation with FUSB3307
In Figure 6, FUSB3307 controls the CATH pin voltage
which is tied to the COMP pin of the buck−boost which
directly regulates the output voltage to 5 V. The ratio of
R9:(R8+R9) is expected to be 1:10 to achieve 5 V on VCC
upon power up which is typically R8 = 120 kohms and R9
= 13.3 kohms.
It is expected that a capacitor, C3 is connected externally
(typically 1 mF) from VDD to ground to provide energy
storage. VDD is regulated to be at the appropriate voltage for
the internal circuitry for any USB PD contract from 3.3 V
when in a USB PD Programmable Power Supply (PPS)
contract to the highest PPS voltage of 21 V.
In Figure 6, the buck−boost has its feedback FB pin which
has the resistor that also expects a 1:10 resistor divider in
www.onsemi.com
11
FUSB3307
CC1 and CC2 Lines and USB−C Receptacle Assumptions
C1
If a USB−C receptacle is used, CC1 and CC2 are
connected from the receptacle to the FUSB3307’s CC1 and
CC2 pins. If a hardwired connection (called “captive cable”
in Type−C and USB PD specifications) is desired, the CC
line is connected to CC1 (or CC2 if more convenient for
routing) and the VCONN line is connected to CC2 (or CC1)
pin not used above.
The design in the figures above assumes a Type C
receptacle (as opposed to captive cable) and all the following
descriptions are consistent with this configuration. Also
assumed is USB 2.0 only receptacle (D+ and D−) for a power
source application without data (that is, the USB D+ and D−
do not go to a USB PHY). All SuperSpeed lines (TX1+,
TX1−, RX1+, RX1−, TX2+, TX2−, RX2+, RX2−) are left
unconnected and the SBU1 (Side Band Use) and SBU2 pins
are not used.
USB Type−C
Detection
and Gate
Drivers
VBUS
DISC
CC2
R1
PD 3.0
Device Policy
Manager,
Policy
Engine,
Protocol &
PHY Layers
D−/PDIV0
D+/PDIV1 R3
R2
CC1
C2
VDD
C3
ESD
7272
ESD
7272
CV/CC
Regulation
2 ESDM3551’s
FUSB3307
Figure 9. CC1 and CC2 Proximity to VBUS Within
Type−C Connector
Internally, the FUSB3307 pulls up CC1 and CC2
individually to VDD with currents that advertise 3 A
capability for this power source per USB Type C
specification. When a Sink device is connected to the
USB−C receptacle, the voltages on CC1 and CC2 will drop
down per Type C specification. The FUSB3307 will detect
a legitimate attach with the Sink and accordingly turn on the
VBUS FET Q1 (see VBUS Operation descriptions below).
If this design needs high−voltage, short−to−VBUS
protection on CC1 and CC2, the FUSB3307 protects the
CC1 and CC2 lines internally to the highest VBUS voltage
that is possible for USB PD. FUSB3307 also detects CC1
and CC2 pins in this over−voltage state and goes into the
Type C Disabled state. But it will take a finite amount of time
to detect an over−voltage event on CC1 or CC2, turn off the
load switch FET Q1 and discharge VBUS and thus the
over−voltage protection on CC1 and CC2 to protect these
I/Os. The CC1 and CC2 connector pins are physically close
to the VBUS connector pins which is why this need arises
more often than not as highlighted in Figure 9.
For USB PD traffic, per specification, the CC1 (and CC2)
line needs a capacitor to ground that is between 200 pF and
600 pF to minimize noise coupling from other signals within
the connector (especially if D+ and D− USB 2.0 data is sent
through the USB−C connector). Since the FUSB3307 has
very little internal capacitance on the CC1 and CC2 lines
(cReceiver in the electrical tables above), most of this has
to be supplied externally. The recommended value is 390 pF
capacitors from CC1 to ground and CC2 line to ground (C1
and C2 in Figure 5 and Figure 6) and the voltage rating is
dependent on the decision for high voltage protection above.
VBUS Operation
VBUS from the USB−C connector is typically connected
to a load switch NFET (Q1) source terminal whose gate
terminal is driven by the FUSB3307 gate driver via the
GATE pin. There isn’t a need for putting a resistor between
GATE pin and the gate of Q1 since when the load switch is
first turned on, upon attach of a Sink device via the USB−C
connector, the Sink device is not allowed to draw more than
500 mA. However, if desired for a soft turn−on of the FET,
a small (10 ohms typical) resistor can be placed between the
FUSB3307 GATE pin and the gate terminal of Q1. The drain
terminal of Q1 is connected to the power VCC which is at
5 V in the normal detached operation or in an initial USB−C
attach.
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12
FUSB3307
Figure 10. VBUS Discharge by FUSB3307 via DISC Pin
VBUS is discharged through a resistor (R1) via the DISC
pin of the FUSB3307 as shown in the highlighted section in
Figure 10.
The external resistor R1 value is dependent on the total
bulk capacitance (C8) of this power source so that VBUS is
discharged within the time limits dictated by USB PD. A
typical value for R1 is 39 W, 1 W and in addition, there is
internal resistance that causes a expected discharge current
USB Type C specification requires that the supply voltage
is not sourced on VBUS until an attach per Type C
specification has been determined. Dual back−to−back
FET’s for the load switch are not needed for reverse voltage
protection since it is unlikely that VBUS is charged from an
external source. For interoperability with legacy connectors,
there is a case where a Type A to Type C cable is first plugged
into a Type A port of a power source which then supplies 5 V
on VBUS of the cable. Then the Type C connector is plugged
into this design which is not plugged into the AC outlet nor
gets it power from the DC input depending on the design.
The 5 V from the cable will forward conduct through the Q1
FET and charge the bulk capacitor C8. This doesn’t cause an
issue, since the FUSB3307 will power up, check the CC1
and CC2 lines and realize it is not a legitimate Sink device
plugged in and stay detached. Upon unplugging the A to C
within the FUSB3307 in its discharge path (I
in the
DISC −Sink
electrical tables above). If the load current to the Sink is
sufficient (exceeds for
I
t
CS−EN−DSCG
CS−EN−DSCG
debounce time) such that the internal discharge is not
needed, then the FUSB3307 will automatically disable
internal discharge.
Upon power up, the FUSB3307 will discharge VBUS in
case there is any voltage on VBUS since the only way a Sink
can be attached per Type C specification is if VBUS is
discharged to ground (below VSafe0V) upon attach. The
discharge resistance limits are governed by the Type C
specification when not sourcing power on VBUS
cable, the discharge resistance (R
in the electrical
DISC−BUS
tables above) will discharge VBUS to ground if the input
voltage is still unavailable. Even if the input power is
supplied to this design during this incorrect connection,
VCC will regulate to 5 V which will prevent the previously
forward bias body diode of Q1 FET from conducting and the
FUSB3307 will wait for a legitimate Sink to be attached
before turning on FET Q1. The maximum bulk capacitance
is specified in the Type C specification to handle this fault
case as shown in Table 5 from the USB Type C specification
so as to allow for just one FET use for optimum efficiency.
(R
DISC−BUS
in the electrical tables above). It is preferred that
no external load/discharge resistor is connected to VBUS
other than R1 to the FUSB3307 discharge DISC pin.
A TVS diode connected from VBUS to ground and shown
in the figures ([SZ]ESD7241) allow operating voltages up
to 24 V covering the entire VBUS range of 3.3 V to 21 V for
a USB PD PPS contract. This can be replaced by a TVS that
covers the VBUS range for the use case of this design if
needed.
Table 5. TYPE−C SPECIFICATION FOR VBUS BULK CAPACITANCE
Symbol
Notes
Min
Max
Units
VBUS
Capacitance
Capacitance for source−only ports between VBUS and GND pins on
receptacle when VBUS is not being sourced.
3000
mF
Capacitance for DRP ports between VBUS and GND pins on recep-
tacle when VBUS is not being sourced.
10
mF
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13
FUSB3307
Capacitance to ground on the connector side VBUS
The current is sensed via a small resistor R4 (5 mW
typically) connected between the USB−C connector ground
and the main ground plane of the power source (secondary
side ground for offline design) as shown in Figure 12.
connection (source of Q1) can be added if needed but it
hasn’t been shown in the application diagrams above. If
added, it is recommended it doesn’t exceed 1 mF for
recovery from the source−source case mentioned above.
Voltage and Current Sensing Operation
As mentioned above (see Power Up and Assumptions),
the resistor ratio from VCC to ground formed by resistors R8
and R9 (typically 1:10 ratio where R8=120k and R9=13.3k)
and sensed via FUSB3307 VFB pin will sense the voltage
for VCC in order to set a new voltage. For Figure 5 offline
design, this will be done via the FUSB3307 CATH pin, the
opto−coupler, resistor R10 and the primary side PWM
controller operation. R11 provides a bias current to the
CATH pin feedback circuit within the FUSB3307 and is
optional. For Figure 6 buck−boost design, this will be done
via the FUSB3307 CATH pin controlling the buck−boost
PWM via its COMP pin. The FUSB3307 will automatically
control the CATH pin based on the desired voltage as
determine by the USB PD contract and the existing VCC
voltage sensed by VFB. If FUSB3307’s PD communication
is not responded to by the Sink upon initial attach, the
FUSB3307 will continue with 5 V VBUS Type C operation
until the Sink detaches. The external compensation network
formed by C6/R7/C7 and R6/C5 need to be selected to
achieve stable operation over the range of VBUS voltage
and current transitions as shown in Figure 11.
Figure 12. Current Sense Network
A low pass filter formed by R5/C4 provides a stable signal
for IS+ and IS− pins of the FUSB3307 to sense this current
for over−current protection for fixed voltage PD contracts,
constant current operation for PPS contracts and cable
compensation if selected from the trim table (Table 6). It is
expected that the USB−C connector ground is connected
only to the current sense network resistors R4 and R5 and the
connector TVS ground connections and not to the main
ground plane of the NCV81599 for the DC/DC design or
secondary side power ground for the offline design
(FUSB3307 ground connection). However, the FUSB3307
consumes very little current and so it should have a
negligible impact on this current sensing if the FUSB3307
ground connection is on the USC−C connector ground if it
is more convenient in the Printed Circuit Board (PCB)
layout.
When in a PPS contract, if a PPS_Status message is
requested, the FUSB3307 will measure the current with an
internal 10−bit Analog to Digital Converter (ADC) based on
the above description and report it back to the Sink on the
PPS_Status message. The voltage is also reported back but
it is measured off VCC with the ADC not VFB pin since the
VFB pin is only used for voltage feedback. Thus if the
voltage feedback resistor divider connected to VFB is
modified to be slightly different from the 1:10 ratio
expected, the voltage sensing for this PPS_Status message
will not be affected.
Figure 11. Compensation Network for Constant
Voltage / Constant Current (CV/CC) Feedback
For the offline design, C10 may be needed as well. For the
DC/DC design, there may be a need for additional
compensation networks from COMP pin to ground or from
COMP to the NCV81599 supply.
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14
FUSB3307
USB 2.0 Data Lines
2.0 data signals. For the automotive buck−boost design
(Figure 6), short−to−VBUS protection is shown via the
NIV1241 that contain TVS diodes and FETs to keep the
FUSB3307 D+ and D− lines less than 5 V as shown in
Figure 13.
The USB 2.0 Data Lines D+ and D− can be externally
connected together via a 100 ohms resistor to provide the
maximum power, a legacy USB device can take, which is
1.5 A per USB Battery Charging v1.2 (BC1.2) specification.
This will usually be the case when a USB−C to micro−B
cable is plugged into this design where this adapter cable has
the required Sink Rd resistors within it to allow the
FUSB3307 to recognize a Type C attach and to source 5 V
on VBUS. The Sink will go through BC1.2 steps of primary
and secondary detection to detect a Dedicated Charging Port
(DCP) via this resistor connection of D+ and D− and takes
1.5 A maximum from VBUS.
Figure 13. D+ and D− Pin Protection Provided by the
If selected by the Trim table (Table 6), to attach to certain
phones that require resistor dividers on D+ and D− then
connect D+ and D− to the FUSB3307 with small (22 W
typical) resistors which auto−detects which type of legacy
Sink is plugged in and automatically provides the legacy
device with the appropriate power level it needs to charge.
Note this power level is controlled by the device itself not the
power source which is typical of most legacy USB power
systems. The FUSB3307 will allow for 5 V at a maximum
of 3 A for even legacy devices which will take at most either
1.5 A or 2.4 A for most legacy devices.
D+ and D− can also be connected to a USB Physical Layer
(PHY) controller for using these lines for data traffic. In that
case, the USB PHY is expected to advertise itself as a
Charging Downstream Port (CDP) per BC1.2 so that the
Sink can take a maximum of 1.5 A of power.
NIV1241
Power Delivery Operation
FUSB3307 advertises source capabilities and responds to
PD message completely autonomously following the USB
PD 3.0 with PPS and Type C specifications. For more details
on the USB PD messages please refer to the specification
references mentioned below (See Specification References
on page 19). Similarly the references mention the Type C
and the BC1.2 specifications as well for further information.
To allow for a variety of designs, the following table has
a number of trim options to accommodate almost every
design. The following Table 6 lists out the various options.
While all these options exist, they can only be obtained from
ON Semiconductor if requested and once delivered, the trim
option cannot be changed. The default trim option column
below is for a 60 W design that uses 3 A cables and is for a
USB Power Delivery (PD) 3.0 design with Programmable
Power Supplies (PPS) and Fixed Supplies. In the future
more default options will be available for general purpose
use with likely 30 W, 45 W and 90 W power levels in
addition to the 60 W option.
D+ and D− are low voltage pins (6 V absolute maximum
voltage) and are not expected to be shorted to VBUS when
VBUS goes higher than 6 V. The TVS diodes connected to
D+ and D− shown in the figure (ESD7104) allow operating
voltages up to 5 V for the offline design (Figure 5) and
typically D+ and D− are 3.3 V signals when used for USB
Table 6. FUSE TRIM (NOTE 7) OPTION TABLE
#
1
2
3
Function
Trim Option
Default Option
60 W
Output Power
PD Power (PDP) from 16 W to 100 W in 1W increments
Four choices of 50 mV/A, 100 mV/A, 150 mV/A and Disabled
Cable Compensation
5 A Power Source
Disabled
0 = Max current is 3 A, no eMarker detection
1 = Max current is 5 A, eMarker detection needed
0 = Max current = 3 A,
no eMarker detection
4
5
6
Charging Output OVP
Charging Output UVP
Four choices of OVP thresholds: 115%, 120%, 125% and 130%
Four choices of UVP thresholds: 60%, 65%, 70% and Disabled
120% OVP
65% UVP
D+/D− versus
PDIV0/PDIV1
00: D+/PDIV1=D+, D−/PDIV0=D− (SOIC package without PDIV2 pin)
01: D+/PDIV1=PDIV1, D−/PDIV0=PDIV0 (SOIC package without PDIV2 pin)
10: D+/PDIV1=PDIV1, D−/PDIV0=PDIV0 PDIV2 standalone pin
(QFN package)
00 for SOIC package
11 for QFN package
11: D+/PDIV1=D+, D−/PDIV0=D− PDIV2 standalone pin (QFN package)
7
Support PD 3.0
0 = Enable PD 2.0
1 = Enable PD 3.0
1 = Enable PD 3.0
7. ”Trim Options” means feature programmability to create new functional options in a manufacturing test program by trimming semiconductor
fuses.
www.onsemi.com
15
FUSB3307
When a Sink device is connected via the USB−C
as the FUSB303. Subsequent to the initial attach, the
FUSB3307 will send out PD packets to advertise source
capabilities as selected by the trim options in Table 6. Using
the Default FUSB3307 Trim options, the FUSB3307 will
source 60 W by sending out a PD Source_Capabilities
message on the CC line (either CC1 or CC2 depending on
connector plug orientation) using PD communication
messages. The supplies advertised for the default trim option
are fixed supplies and PPS supplies shown in Table 7:
connector, as mentioned above, the FUSB3307 will detect
a legitimate Type C attach and drive the GATE pin to turn on
the VBUS load switch Q1. The initial voltage on VBUS is
always 5 V (4.75 V to 5.5 V voltage range) and the CC pin
will advertise 3 A capability which is the maximum power
allowed by a Type C (without PD) port. FUSB3307 is not
expected to be used below 15 W power level since
ON Semiconductor has other Type C only controllers such
Table 7. DEFAULT TRIM OPTION ADVERTISED PD SOURCE CAPABILITIES
[Augmented] Power Data Object
Output Voltage
Maximum Sink Current Expected
Current Protection
Over Current Protection
Over Current Protection
Over Current Protection
Over Current Protection
Over Current Protection
Current Limit Protection
PDO1
PDO2
PDO3
PDO4
PDO5
APDO1
5 V
3 A
3 A
3 A
3 A
3 A
3 A
9 V
12 V
15 V
20 V
3.3 V min, 21 V max
The Sink will select one of these offerings and enter into
a PD explicit contract with the FUSB3307 which is the first
step of all subsequent PD communication. If the Sink selects
an illegal data object number or requests an illegal current
level, the FUSB3307 will reject the request. A short amount
of time after this reject message is sent, the FUSB3307 will
resend its Source_Capabilties message and expect a valid
request.
If a 5 A capability is chosen from the trim table (Table 6)
above then the FUSB3307 will use USB PD Discover
Identity messages to interrogate the capabilities of the cable
attached to it to ensure that it is a 5 A capable cable before
the FUSB3307 advertises 5 A source capabilities. The
FUSB3307 supplies the VCONN power needed to support
this discovery process as specified in the USB PD and
Type C specification which eliminates the need for an
external VCONN power source and multiple power
switches. If the cable is only 3 A, even though the
FUSB3307 can support 5 A, the advertised capabilities will
all drop down to 3 A. This will be done on the first source
capabilities advertised but there is an indication in the USB
PD Status message sent to indicate that the source is 5 A
capable but the cable has limited the source capabilities to
3 A. In Table 8 the section of the SOP Status Data Block
(SDB) is shown that communicates this power limitation.
The FUSB3307 follows all USB PD specifications
including dropping down to USB PD 2.0 operation when it
detects a USB PD 2.0 Sink and a USB PD 2.0 cable eMarker
(if applicable). All subsequent operation will follow the
USB PD 2.0 specification until the FUSB3307 is reset via a
Hard Reset message or undergoes a power cycle.
Standby Operation
When the FUSB3307 is in standby, where the source
power supply still has to be maintained at 5 V via the CATH
pin for a typical Type C connection but no Sink device has
been attached to the FUSB3307, then the current consumed
is just I
( < 870 mA typical). This low standby
CC−GREEN
current allows for all the energy standard specifications to be
well exceeded for offline designs (typically the FUSB3307
within the offline design can achieve 21 mW standby
power).
PDIV0, PDIV1 and PDIV2 Options
FUSB3307 can adjust the output power from the trim
table (Table 6) to have any PDP (Power Delivery Power)
from 16 W to 100 W (called TrimPDP here) in 1 W
increments. However, in some applications in may be
advantageous to trim all FUSB3307 devices to 60 W PDP
and use them in both single port and dual port
configurations. For the dual port configuration, the PDP
would need to be halved for assured capacity charger ports
and PDIV2 pin does just that – cuts the trimmed 60 W PDP
in half to 30 W. For further divider ratios, PDIV1 and PDIV0
can be used as well.
PDIV2 is available only in the QFN version of the
FUSB3307 while PDIV0 and PDIV1 share their
functionality with the D− and D+ pins respectively in both
the QFN and SOIC package options. For the PDIV2 pin, the
selection of power is shown in Table 9.
Table 8. PD Status Message to Sink Showing Power is
Limited by the Cable
Offset
Field
Bit
0
Description
5
Power
Status
...
1
Source power limited due to
cable supported current
2
...
...
6...7
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16
FUSB3307
In all the above calculations, no Advertised PDP will ever
Table 9. PDIV2 Pin Changing Advertised PD Power
go below 16 W minimum if in a USB PD contract. For
example, if TrimPDP=100 and when PDIV0, PDIV1 and
PDIV2 Pin State
Advertised PDP (Power Delivery Power)
100% of TrimPDP
1
0
PDIV2
pins
are
available
and
they
are
50% of TrimPDP
[PDIV2:PDIV1:PDIV0] = 001 then Advertised PDP is
25 W (100W*25%). However if TrimPDP=60, then
Advertised PDP is 16 W not 15 W (60W*25%).
With the SOIC package and PDIV0 and PDIV1 pins
selected, the power can be controlled as shown below. In this
case there is no PDIV2 pin and the PDIV0 and PDIV1 pins
are used to trim power, as shown in Table 10.
When any of these pins, PDIV0, PDIV1 and PDIV2 are
changed, the connected PD Sink has to ask for Source
Capabilities to get these new capabilities or if this Sink or the
FUSB3307 executes a Soft_Reset or Hard Reset which causes
the new advertised capabilities to be sent by the FUSB3307.
Alternatively recovery from any protection operation would
cause the FUSB3307 to advertise the new PDP values based
on the PDIV0, PDIV1 and PDIV2 pins setting.
Table 10. PDIV0 and PDIV1 Pins Changing Advertised
PD Power
Advertised PDP
(Power Delivery Power)
100% of TrimPDP
75% of TrimPDP
PDIV1 Pin State PDIV0 Pin State
1
1
0
0
1
1
1
0
Protection Operation
FUSB3307 has a number of ways it protects itself as
shown in Table 12.
50% of TrimPDP
25% of TrimPDP
If PDIV2 is also available (i.e. QFN package) and in the
above trim table (Table 6) the pins D+/PDIV1 and
D−/PDIV0 allow PDIV0 and PDIV1 to be available as pins,
then this is the PDP advertised, as shown in Table 11.
Table 11. PDIV0, PDIV1 and PDIV2 Pins Changing
Advertised PD Power
PDIV2
Pin State
PDIV1
Pin State
PDIV0
Pin State
Advertised PDP (Pow-
er Delivery Power)
1
1
1
1
0
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
100% of TrimPDP
87.5% of TrimPDP
75% of TrimPDP
62.5% of TrimPDP
50% of TrimPDP
37.5% of TrimPDP
25% of TrimPDP
12.5% of TrimPDP
Table 12. Protection Modes Available
Symbol
Description
Pin(s) Used
VCC
Package
OVP
UVP
Output Voltage Over Voltage Protection
Output Voltage Under Voltage Protection
Over Current Protection
SOIC & QFN
SOIC & QFN
SOIC & QFN
SOIC & QFN
QFN only
VCC
OCP
IS+ & IS−
none
I_OTP
Internal Over Temperature Protection
External Over Temperature Protection
CC1 or CC2 Over Voltage Protection
CC1 or CC2 VCONN Over Current Protection
E_OTP
CC_OVP
VCONN_OCP
NTC
CC1 / CC2
CC1 / CC2
SOIC & QFN
SOIC & QFN
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17
FUSB3307
OVP and UVP are sensed via an internal resistor divider
For compliance with the USB PD specification, the
FUSB3307 will trigger UVP whenever VCC is below
that divides VCC by 10 to determine the voltage from the
power source. CC1 and CC2 are directly sensed for over
voltage. For E_OTP (QFN package option only), a pin NTC
is available that is connected to an NTC resistor to ground
usually in parallel with another resistor to ground for
linearity. For I_OTP (SOIC and QFN packages), an internal
temperature monitor is used. For all faults except
VCONN_OCP fault, upon detection, the FUSB3307 will
disable the Type C connection with the Sink (no pull−up on
CC), shut off VBUS load switch and keep monitoring the
fault. Once the fault has been removed, the FUSB3307 starts
V
CC
. This allows protection for a direct short of VBUS
−OFF
to ground separately or in conjunction with the OCP fault
described below. If VCC < V fault is triggered, then
−OFF
CC
to resume normal operation, VCC has to go below V
LATCH
to reset the FUSB3307 to exit this fault condition.
Over Current Protection (OCP) and Constant Current
Limit (CL)
If VBUS is shorted to ground, either the UVP fault
described above could trigger or the OCP fault, or both.
FUSB3307 senses the current via a small R4 resistor (5 mW
typical) as described in the Voltage and Current Sensing
section above. The OCP fault is triggered at 120% of the
maximum current for the requested Power Data Object
up at 5 V after t
Sink.
seconds and reconnects with the
2S_AR_NM
Output Over Voltage Protection (OVP)
(PDO) for fixed supplies only (I
typically 3.6 A for a
FUSB3307 has built−in OVP based on the Trim Table
(Table 6). For the default OVP case, whenever VCC, as
sensed by an internal 1:10 resistor divider, exceeds
CS−3A
3 A maximum fixed supply current). Once this OCP fault
occurs, the FUSB3307 protects the system as described in
the Protection Operation section above. An Alert message
is sent upon the FUSB3307 establishing an explicit contract
with the Sink and a PD “Status” message from the
FUSB3307 will include the OCP history.
For PPS APDO’s (Augmented Power Data Objects),
Constant Current Limiting (CL) is used as specified in the
USB PD specification where the voltage will drop to a low
value based on keeping the current constant and equal to the
requested PPS current. In this case UVP described above
K
(typically 120%) of the requested VCC from the
CC−OVP
power source for a debounce time of t , then the OVP
D−OVP
fault would be triggered. Upon detection, the FUSB3307
will disable the Type C connection with the Sink (no pull−up
on CC), shut off VBUS load switch and keep monitoring
VCC to determine if the OVP is still present. When OVP is
removed, a timer is started which when expired in t
2S_AR
seconds, causes the FUSB3307 to reestablish the Sink Type
C connection with the initial 5 V VBUS supplied as if it were
initially attached.
will trigger if VCC drops below V
since any voltage
−OFF
CC
from the lowest 3.3 V – 5% to the PPS requested voltage
could occur with current limiting. If the PPS current limit is
changed with a new PD Request message, the VCC voltage
may change accordingly to a new value based on the current
limiting function. An Alert message is sent whenever there
is a switch from Constant Current Limit (CL) to Constant
Voltage (CV) mode and vice versa. For PPS_Status
messages, this flag that shows whether the FUSB3307 is in
CL or CV mode, is sent along with the VCC voltage and load
current as sensed by R4 to monitor the FUSB3307 while it
provides PPS voltages and currents.
During transitions between VCC voltages, the OVP
circuitry is blanked or disabled for t
time to ensure
BNK−OVP
that false triggering of OVP doesn’t occur. To ensure safe
operation over all voltages of VCC, the maximum VCC
voltage is limited to V
CC−OVP−MAX.
Output Under Voltage Protection (UVP)
FUSB3307 has a built−in UVP based on the Trim Table
(Table 6). For the default UVP case, whenever VCC, as
sensed internally, is below K
(typically 65%) of the
CC−UVP
requested output voltage from the power source for a
debounce time of t , then the UVP fault would be
D−UVP
Over Temperature Protection (I_OTP and E_OTP)
FUSB3307 has two different over temperature faults,
E_OTP and I_OTP. For E_OTP, when the QFN package is
used, there is a NTC pin that is expected to be connected to
an NTC resistor in parallel with a regular resistor for
triggered. No PD Alert messages are sent for this fault.
During transitions between VCC voltages, the UVP
circuitry is blanked or disabled for t
time to ensure
BNK−UVP
that false triggering of UVP doesn’t occur.
For PPS contracts, if current limiting causes the voltage to
decrease, the UVP fault will not trigger at 65% of VCC since
linearity. The FUSB3307 provides a I
current source
NTC
(typically 60 mA) on the NTC pin to bias this NTC resistor
so that an internal A/D converter measures the external
temperature as shown in Figure 14.
all voltages from the requested voltage to V
lowest voltage, are valid.
the
−OFF,
CC
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18
FUSB3307
VCC
FAULT
9R
R
Protection
Block
V
IN−1:10
OVP/UVP/
OCP
V
vdd
V
CS−AMP
COMR
Protection
V
V
CS−AMP
Analog to Digital
Converter
NTC
IN−1:10
Internal temp.
CATH
Figure 14. Protection Section of Block Diagram for UVP, OVP, OCP, and OTP Faults
This NTC measured temperature is useful for dynamic
to start protecting the system when the CC voltage is beyond
it normal operating range. If the CC voltage is above
monitoring by the Sink via FUSB3307 provided PD Status
messages which contains this NTC temperature in this
package option. If this temperature exceeds a warning
threshold (100°C for a NTC resistor of 100 kW 1%, B25/50
= 4300K 1% to ground in parallel with a 20 kW 1% to
V
(if CC is CC1 pin) or above V
(if CC is
CC1−OVP
CC2−OVP
CC2 pin) threshold for t
debounce time, then
CC−OVP−DEB
the FUSB3307 protects the system by triggering this fault
and executing protection as described in Protection
Operation section above.
ground) for t
debounce time, then a PD Alert
NTC−DEB
message is sent to the Sink indicating this temperature
warning. If however, the E_OTP threshold is exceeded
(110°C for a NTC resistor of 100 kW 1%, B25/50 = 4300K
1% to ground in parallel with a 20 kW 1% to ground) for
VCONN Over Current Protection (VCONN_OCP)
FUSB3307 will turn on VCONN whenever it needs to
read the eMarker in the cable only if 5 A capability is chosen
from the trim table (Table 6) above and this design has a
Type C connector and not a hardwired captive cable. When
VCONN is sourced, per USB PD specification only
100 mW maximum (5 V with 20 mA for the FUSB3307)
needs to be supplied for a USB 2.0 source application. If the
t
debounce time, then an E_OTP fault is triggered
NTC−DEB
as described in the Protection Operation section above.
Upon re−establishing an explicit contract with the Sink, the
FUSB3307 sends an Alert to let the Sink know it previously
experienced an Over Temperature Protection event.
The SOIC package version of the FUSB3307 doesn’t have
an NTC pin and so the internal die temperature is monitored.
VCONN current exceeds I
(typical 50 mA) for
CONN_OCP
t
then the FUSB3307 will disable the VCONN
VCONN_OCP
supply and abort the eMarker discovery process. The default
maximum current of 3 A will be used for all source
capabilities for USB PD messages in the latter case and the
normal PD messaging will occurs without interruption. No
Alert messages will be sent but the PD Status message will
have a bit to indicate that the cable limited the FUSB3307
from advertising 5 A source capabilities.
When the die temperature exceeds T
threshold for
INT−W
t
debounce time, then a PD Alert message is sent to
NTC−DEB
the Sink indicating this temperature warning. If however, the
threshold is exceeded for t debounce
T
INT−OTP
NTC−DEB
time, then an I_OTP fault is triggered and executing
protection as described in Protection Operation section
above. The FUSB3307 sends an Alert to let the Sink know
it previously experienced an Over Temperature Protection
event. This internal die temperature is monitored also in the
QFN package option and either an E_OTP fault (based off
the NTC pin voltage) or an I_OTP fault causes the
FUSB3307 to disconnect and shut off VBUS. The
temperature warning for the QFN package is only triggered
via the NTC resistor not the internal die temperature.
Specifications References
• Universal Serial Bus Power Delivery specification
revision 3.0 version 2.0 + ECNs up to 07 February, 2020
• Universal Serial Bus Type C Cable and Connection
Specification release 2.0, dated August, 2019
• USB Battery Charging Specification, revision 1.2,
dated December 7, 2010
CC1 and CC2 Over Voltage Protection (CC_OVP)
FUSB3307 protects against the CC1 and CC2 connector
pins being shorted to VBUS up to 26 V and it has the ability
• Universal Serial Bus Power Delivery specification
revision 2.0 version 1.3, dated 12 January, 2017
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19
FUSB3307
PACKAGE DIMENSIONS
SOIC−14 NB
CASE 751A−03
ISSUE L
NOTES:
D
A
B
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE PROTRUSION
SHALL BE 0.13 TOTAL IN EXCESS OF AT
MAXIMUM MATERIAL CONDITION.
4. DIMENSIONS D AND E DO NOT INCLUDE
MOLD PROTRUSIONS.
14
8
7
A3
E
H
5. MAXIMUM MOLD PROTRUSION 0.15 PER
SIDE.
L
DETAIL A
1
MILLIMETERS
DIM MIN MAX
INCHES
MIN MAX
13X b
M
M
B
0.25
A
A1
A3
b
D
E
1.35
0.10
0.19
0.35
8.55
3.80
1.75 0.054 0.068
0.25 0.004 0.010
0.25 0.008 0.010
0.49 0.014 0.019
8.75 0.337 0.344
4.00 0.150 0.157
M
S
S
0.25
C A
B
DETAIL A
h
A
X 45
_
e
H
h
L
1.27 BSC
0.050 BSC
6.20 0.228 0.244
0.50 0.010 0.019
1.25 0.016 0.049
5.80
0.25
0.40
0
0.10
M
A1
e
M
7
0
7
_
_
_
_
SEATING
PLANE
C
SOLDERING FOOTPRINT*
6.50
14X
1.18
1
1.27
PITCH
14X
0.58
DIMENSIONS: MILLIMETERS
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
www.onsemi.com
20
FUSB3307
PACKAGE DIMENSIONS
QFNW20 4x4, 0.5P
CASE 484AT
ISSUE O
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