NCN5150 D

NCN5150
Wired M-BUS Slave
Transceiver
Description
The NCN5150 is a single-chip integrated slave transceiver for use in
two-wire Meter Bus (M-BUS) slave devices and repeaters. The
transceiver provides all of the functions needed to satisfy the
European Standards EN 13757−2 and EN 1434−3 describing the
physical layer requirements for M-BUS. It includes a programmable
power level of up to 2 (SOIC version) or 6 (NQFP version) unit loads,
which are available for use in external circuits through a 3.3 V LDO
regulator.
The NCN5150 can provide communication up to the maximum
M-BUS communication speed of 38,400 baud (half-duplex).
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NQFP−20
MN SUFFIX
CASE 485E
MARKING DIAGRAMS
Features
• Single-chip MBUS Transceiver
• UART Communication Speeds Up to 38,400 baud
• Integrated 3.3 V VDD LDO Regulator with Extended Peak Current
•
•
•
•
•
•
•
•
•
•
•
SOIC−16
D SUFFIX
CASE 751B
Capability of 15 mA
Supports Powering Slave Device from the Bus or from External
Power Supply
Adjustable I/O Levels
Adjustable Constant Current Sink up to 2 or 6 Unit Loads Depending
on the Package
Low Bus Voltage Operation
Extended Current Budget for External Circuits: at least 0.88 mA
Polarity Independent
Power-Fail Function
Fast Startup − No External Transistor Required on STC Pin
Industrial Ambient Temperature Range of −40°C to +85°C
Available in:
♦ 16-pin SOIC (Pin-to-Pin Compatible with TSS721A)
♦ 20-pin QFN
These are Pb-free Devices
20
1
NCN
5150
ALYW
G
NQFP−20
16
NCN5150
ALYYWWG
1
SOIC−16
A
L
Y, YY
W, WW
G or G
= Assembly Location
= Wafer Lot (optional)
= Year
= Work Week
= Pb-free Package
ORDERING INFORMATION
See detailed ordering and shipping information in the package
dimensions section on page 10 of this data sheet.
Typical Applications
• Multi-energy Utility Meters
♦
♦
♦
♦
Water
Gas
Electricity
Heating systems
Related Standards − European Standard
EN 13757−2, EN 1434−3
For more information visit www.m-bus.com
© Semiconductor Components Industries, LLC, 2015
May, 2015 − Rev. 3
1
Publication Order Number:
NCN5150/D
RX
VDD
BUSL2
18
17
16
VB
RIS
RXI
NCN5150
20
19
GND
1
15
BUSL1
2
14 VS
BUSL2
3
VB
4
12 TX
5
11
NCN5150
1
16
BUSL1
2
15
GND
STC
3
14
RIS
RIDD
4
13
RXI
12
RX
NCN5150
13 VIO
6
7
8
9
STC
RIDD
PFb
SC
QFN20
TXI
10
SOIC16
PFb
5
SC
6
11
VDD
TXI
7
10
VS
TX
8
9
VIO
Figure 1. Pin Out NCN5150 in 20-pin NQFP and 16 Pin SOIC (Top View)
Table 1. NCN5150 PINOUT
Pin Number
Signal Name
Type
NCN5150 SOIC
NCN5150 QFN
BUSL1
Bus
16
2
BUSL2
Bus
1
3
VB
Power
2
4
Rectified bus voltage
STC
Output
3
6
Storage capacitor pin. Connect to bulk storage capacitor
(minimum 10 mF, maximum 330 mF−2,700 mF − see Table 9)
RIDD
Input
4
7
Mark current adjustment pin.
Connect to programming resistor
PFb
Output
5
8
Power Fail, active low
SC
Output
6
9
Mark bus voltage level storage capacitor pin.
Connect to ceramic capacitor (typically 220 nF)
TXI
Output
7
11
UART Data output (inverted)
Pin Description
MBUS line. Connect to bus through 220 W series resistors.
Connections are polarity independent
TX
Output
8
12
UART Data output
VIO
Input
9
13
I/O pins (RX, RXI, TX, TXI, PFb) high level voltage
VS
Output
10
14
Gate driver for PMOS switch between bus powered operation
and external power supply
VDD
Power
11
16
Voltage regulator output.
Connect to minimum 1 mF decoupling capacitor
RX
Input
12
17
UART Data input
RXI
Input
13
18
UART Data input (inverted)
RIS
Input
14
20
Modulation current adjustment pin
GND
Ground
15
1
Ground
NC
NC
−
5, 10, 15, 19
EP
Ground
−
EP
Not connected pins. Tie to GND
Exposed Pad. Tie to GND
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2
NCN5150
PFb
VIO
VIO
Buffer
Power
Fail
Detect
VIO_BUF
VB_INT
BUSL1
VB
CS1
BUSL2
RIDD
VIO_BUF
SC
STC
VS
VS
Driver
TX
Receiver
STC
Voltage
Monitor
TXI
ECHO
RXI
VDD
3.3 V
LDO
STC
Clamp
Transmitter
RX
CS_TX
Thermal
Shutdown
POR
RIS
NCN5150
GND
Figure 2. NCN5150 Block Diagram
Table 2. ABSOLUTE MAXIMUM RATINGS (Note 1)
Symbol
Parameter
Min
Max
Unit
TJ
Junction Temperature
−40
+150
°C
TS
Storage Temperature
−55
+150
°C
Bus Voltage (|BUSL1 − BUSL2|)
−50
50
V
Voltage on Pin TX, TXI
−0.3
7.5
V
Voltage on Pin RX, RXI, VIO
−0.3
5.5
V
VBUS
VTX, VTXI
VRX, VRXI, VIO
ESDHBM
ESD Rating − Human Body Model
4.0
−
kV
ESDMM
ESD Rating − Machine Model
250
−
V
ESDCDM
ESD Rating − Charged Device Model
750
−
V
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 voltages are referenced to GND.
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NCN5150
Table 3. THERMAL CHARACTERISTICS
Rating
Symbol
Typical Value
Unit
Thermal Characteristics, SOIC−16 − Thermal Resistance, Junction-to-Air
RθJA
125
°C/W
Thermal Characteristics, QFN−20 − Thermal Resistance, Junction-to-Air
RθJA
42
°C/W
NOTE: RqJA obtained with 1S0P (SOIC) or 2S2P (QFN) test boards according to JEDEC JESD51 standard.
Table 4. RECOMMENDED OPERATING CONDITIONS (Notes 2 and 3)
Symbol
TA
VBUS
VIO
Parameter
Min
Max
Unit
−40
+85
°C
1−2 Unit Loads
9.2
42
V
3−6 Unit Loads
9.7
42
V
2.5
3.8
V
Ambient Temperature
Bus Voltage (|VBUSL1 − VBUS2|)
VIO Pin Voltage (Note 4)
2. Refer to ELECTRICAL CHARACTERISTICS and APPLICATION INFORMATION for Safe Operating Area.
3. All voltages are referenced to GND.
4. VSTC must be at least 1V higher than VIO for proper operation.
Table 5. ELECTRICAL CHARACTERISTICS (Note 5)
Symbol
Voltage drop over bus rectifier (VBUS − VB) (RIDD (Note 6) = 4.02 kW)
DVCS
Voltage drop over CS1
(VB − VSTC)
IBUS
DIBUS
ISTC
Total Current Drawn from the Bus, Mark
State
Typ
Max
Unit
−
−
1.25
V
V
RIDD (Note 6) ≥ 13 kW
1.30
−
−
RIDD (Note 6) ≤ 4.02 kW
1.70
−
−
RIDD (Note 6) = 30 kW
−
1.32
1.50
RIDD (Note 6) = 13 kW
−
2.71
3.00
RIDD (Note 6, 7) = 8.45 kW
−
4.10
4.50
RIDD (Note 6, 7) = 6.19 kW
−
5.50
6.00
RIDD (Note 6, 7) = 4.87 kW
−
6.80
7.50
RIDD (Note 6, 7) = 4.02 kW
−
8.22
9.00
−
0.2
2
%
RIDD (Note 6) = 30 kW
0.88
1.05
1.20
mA
Bus Current Stability (over DVBUS = 10 V, RX/RXI = mark)
Idle Current Available for the Application
to Draw from STC and VDD (Including
Current Drawn from IO Pins)
Min
mA
RIDD (Note 6) = 13 kW
2.10
2.35
2.60
RIDD (Note 6, 7) = 8.45 kW
3.10
3.60
4.00
RIDD (Note 6, 7) = 6.19 kW
4.20
4.80
5.40
RIDD (Note 6, 7) = 4.87 kW
5.30
6.10
6.90
RIDD (Note 6, 7) = 4.02 kW
6.50
7.45
8.40
Additional Current Available for the Application when Transmitting a
Space
−
200
−
mA
ICC
Internal Supply Current (RIDD (Note 6) = 13 kW, RX/RXI = mark)
−
359
500
mA
IIO
Current Drawn by the VIO Pin
−0.5
−
0.5
mA
Clamp Voltage on Pin STC (IDD < ISTC)
6.0
6.5
7.0
V
VSTC + 0.3
−
VSTC + 0.8
V
VIO − 0.6
−
VIO
V
0
−
0.6
V
DISTC, space
VSTC, clamp
VB, PFb
Threshold Voltage on VB to Trigger PFb (Note 8)
VPFb, OH
PFb Voltage High (IPFb = −100 mA)
VPFb, OL
PFb Voltage Low (Note 9) (IPFb = 50 mA)
VRIDD
5.
6.
7.
8.
9.
Parameter
DVBR
Voltage on RIDD Pin
VVS, OH
Voltage on VS during High State
(VSTC > VSTC, VDD ON, IVS = −5 mA)
RVS, PD
Pull-down Resistor on VS during Low State
(VDD > 2 V, VSTC > VS)
All voltages are referenced to GND.
Resistor with 1% accuracy.
Only possible in NQFP variant.
PFb comparator has a 70 mV hysteresis.
PFb pin is pulled down with an on-chip resistor of typically 2 MW.
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1.15
1.20
1.25
V
VSTC − 0.4
−
VSTC
V
50
100
150
kW
NCN5150
Table 6. VDD REGULATOR ELECTRICAL CHARACTERISTICS (Note 10)
Parameter
Symbol
VDD
Voltage on VDD (Note 11 ) (IDD < 15 mA)
IDD
Peak Current that can be Supplied by VDD (Note 12)
Min
Typ
Max
Unit
3.1
3.3
3.6
V
15
−
−
mA
IDD, OFF
VBUS = 0 V, VSTC = 0 V
−0.5
−
0.5
mA
VPOR, ON
Power-on Reset Threshold, Release
2.65
2.85
3.15
V
VPOR, OFF
Power-on Reset Threshold, Reset
2.55
2.75
3.00
V
VSTC, VDD ON
Threshold Voltage on Pin STC to Turn On VDD Regulator, Pull
the VS Pin High and Enable the PF Function
5.6
6.0
6.4
V
VSTC, VDD OFF
Threshold Voltage on Pin STC to Turn Off VDD Regulator and
Pull the PFb and VS Pins Low
3.7
4.0
4.3
V
10. All voltages are referenced to GND.
11. Including output resistance of VDD.
12. Average current draw limited by ISTC.
Table 7. RECEIVER ELECTRICAL CHARACTERISTICS (Note 13)
Parameter
Symbol
VT
VSC
ISC, charge
ISC, discharge
CDR
Receiver Threshold Voltage
Mark Level Storage Capacitor Voltage
Min
Typ
Max
Unit
VSC − 8.2
−
VSC − 5.7
V
−
−
VB
V
Mark Level Storage Capacitor Charge Current
−40
−25
−15
mA
Mark Level Storage Capacitor Discharge Current
0.3
0.6
−0.033 ×
ISC, charge
mA
Charge/Discharge Current Ratio
30
40
−
VIO − 0.6
−
VIO
V
(ITX/ITXI = 100 mA)
0
−
0.35
V
(ITX = 1.1 mA)
0
−
1.5
V
0
−
16
mA
VTX, OH,
VTXI, OH
TX/TXI High-level Voltage (ITX/ITXI = −100 mA) (Note 14)
VTX, OL,
VTXI, OL
TX/TXI Low-level Voltage
ITX, ITXI
VTX = 7.5 V, VSTC = 6 V
13. All voltages are referenced to GND.
14. VSTC must be at least 1 V higher than VIO for proper operation.
Table 8. TRANSMITTER ELECTRICAL CHARACTERISTICS (Note 15)
Symbol
Parameter
IMC
Space Level Modulating Current (RRIS = 100 W (Note 16))
Min
Typ
Max
Unit
12.5
15.0
18.0
mA
VRIS
Voltage on RIS Pin
1.2
1.4
1.6
V
VRX, IH, VRXI, IH
RX/RXI Input High
VIO − 0.8
−
5.5
V
VRX, IL, VRXI, IL
RX/RXI Input Low
0
−
0.8
V
Current Drawn or Sourced from RX/RXI Pins (Note 17)
(VIO = 3 V)
±6
−
±30
mA
IRX, IRXI
15. All voltages are referenced to GND.
16. Resistor with 1% accuracy.
17. Including internal pull-up resistor on RX and internal pull-down resistor on RXI.
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NCN5150
APPLICATION SCHEMATICS
VS
VIO
VDD
RBUS1
CVDD
BUSL2
U1
NCN5150
TXI
VB
TVS1
MBUS
TX
BUSL1
RX
mC
RBUS2
RXI
PFb
RIS
SC
RIS
GND
RIDD
CSC
STC
RIDD
CSTC
Figure 3. General Application Schematic
VS
VIO
VDD
RBUS1
CVDD
BUSL2
U1
NCN5150
TXI
VB
TVS1
TX
mC
BUSL1
RX
RBUS2
RXI
PFb
RIS
SC
RIS
GND
CSC
RIDD
RIDD
STC
CSTC
Figure 4. Application Schematic with External Power Supply (Battery)
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MBUS
NCN5150
APPLICATION SCHEMATICS
Q1
VS
VIO
VDD
RBUS1
CVDD
BUSL2
U1
NCN5150
TXI
MBUS
TVS1
VB
TX
BUSL1
RX
mC
RBUS2
RXI
PFb
RIS
SC
RIS
GND
RIDD
CSC
STC
RIDD
CSTC
Figure 5. Application Schematic with Backup External Power Supply
VSTC
VIO
2.2 kW
15 kW
15 kW
VS
VDD
RBUS1
CVDD
U1
TXI
U3
BUSL2
TX
NCN5150
VB
MBUS
TVS1
BUSL1
RX
RBUS2
RXI
PFb
mC
620 W
U2
RIS
SC
GND
RIDD
STC
V STC
RIS
CSC
RIDD
Figure 6. Optically Isolated Application Schematic
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CSTC
NCN5150
Table 9. TYPICAL BILL OF MATERIALS
Reference Designator
Value (Typical)
Tolerance
Manufacturer
Part Number
U1
−
−
ON Semiconductor
NCN5150
ON Semiconductor
1SMA40CAT3G
TVS1
40 V
−
CVDD
> 1 mF
−20%, +80%
RIS
100 W
1%
CSC
220 nF
−20%, +80%
220 W
10%
30 kW
1%
RBUS1, RBUS2
RIDD
CSTC
1 UL
2 UL
13 kW
1%
3 UL (Note 18)
8.45 kW
1%
4 UL (Note 18)
6.19 kW
1%
5 UL (Note 18)
4.87 kW
1%
6 UL (Note 18)
4.02 kW
1%
1 UL
≤ 330 mF
10%
2 UL
≤ 820 mF
10%
3 UL (Note 18)
≤ 1,200 mF
10%
4 UL (Note 18)
≤ 1,500 mF
10%
5 UL (Note 18)
≤ 2,200 mF
10%
6 UL (Note 18)
≤ 2,700 mF
10%
18. 3−6 UL configurations are only possible for the NQFP variant.
APPLICATION INFORMATION
bit, 8 data bits, 1 even parity bit, and a stop bit.
Communication speeds allowed by the M-BUS standard are
300, 600, 2400, 4800, 9600, 19200 and 38400 baud, all of
which are supported by the NCN5150.
The NCN5150 is a slave transceiver for use in the meter
bus (M-BUS) protocol. The bus connection is fully polarity
independent. The transceiver will translate the bus voltage
modulation from master-to-slave communication to TTL
UART communication, and in the other direction translate
UART voltage levels to bus current modulation. The
transceiver also integrates a voltage regulator for utilizing
the current drawn in this way from the bus, and an early
power fail warning. The transceiver also supports an
external power supply and the I/O high level can be set to
match the slave sensor circuit. A complete block diagram is
shown in Figure 2. Each section will be explained in more
detail below.
Bus Connection and Rectification
The bus should be connected to the pins BUSL1 and
BUSL2 through series resistors to limit the current drawn
from the bus in case of failure (according to the M-BUS
standard). Typically, two 220 W resistors are used for this
purpose.
Since the M-BUS connection is polarity independent, the
NCN5150 will first rectify the bus voltage through an active
diode bridge.
Meter Bus Protocol
Slave Power Supply (Bus Powered)
M-BUS is a European standard for communication and
powering of utility meters and other sensors.
Communication from master to slave is achieved by
voltage-level signaling. The master will apply a nominal
+36 V to the bus in idle state, or when transmitting a logical
1 (“mark”). When transmitting a logical 0 (“space”), the
master will drop the bus voltage to a nominal +24 V.
Communication from the slave to the master is achieved
by current modulation. In idle mode or when transmitting a
logical 1 (“mark”), the slave will draw a fixed current from
the bus. When transmitting a logical 0 (“space”), the slave
will draw an extra nominal 15 mA from the bus. M-BUS
uses a half-duplex 11-bit UART frame format, with 1 start
A slave device can be powered by the M-BUS or from an
external supply. The M-BUS standard requires the slave to
draw a fixed current from the bus. This is accomplished by
the constant current source CS1. This current is used to
charge the external storage capacitor CSTC. The current
drawn from the bus is defined by the programming resistor
RIDD. The bus current can be chosen in increments of
1.5 mA called unit loads. Table 5 list the different values of
programming resistors needed for different unit loads, as
well as the current drawn from the bus (IBUS) and the current
that can be drawn from the STC pin (ISTC). ISTC is slightly
less than IBUS to account for the internal power consumption
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NCN5150
of the NCN5150. The RIDD resistor used must be at least 1%
accurate. Note that using 5 and 6 Unit Loads is not covered
by the M-BUS standard.
When the voltage on the STC pin reaches VSTC, VDD ON
the LDO is turned on, and will regulate the voltage on the
VDD pin to 3.3 V, drawing current from the storage
capacitor. A decoupling capacitor of minimum 1 mF is
required on the VDD pin for stability of the regulator. On the
STC pin, a minimum capacitance of 10 mF is required.
Furthermore, the ratio CSTC/CVDD must be larger than 9.
The voltage on the STC pin is clamped to VSTC, clamp by a
shunt regulator, which will dissipate any excess current that
is not used by the NCN5150 or external circuits.
VBUS
VMARK = [21 V, 42 V]
VT = VMARK − 6 V
VSPACE = VMARK − 12 V
t
VTX
VIO
t
VTXI
VIO
t
Figure 7. Communication, Master to Slave
Slave Power Supply (External)
VB
In case the external sensor circuit consumes more than the
allowed bus current or the sensor should be kept operational
when the bus is not present, an external power supply, such
as a battery, is required.
When the external circuitry uses different logical voltage
levels, simply connect the power supply of that voltage level
to VIO, so that the RX, RXI, TX, TXI and PFb pins will
respond to the correct voltage levels. The NCN5150 will still
be powered from the bus, but all communication will be
translated to the voltage level of VIO.
If the external power supply should be used only as a
backup when the bus power supply fails, a PMOS transistor
can be inserted between the external power supply and VDD
as shown in Figure 5. The gate is connected to VS, and will
be driven high when the voltage on STC goes above the
turn-on threshold of the LDO, nl. VSTC, VDD ON. For more
information see the paragraph on the power on sequence and
corresponding Figure 12 on page 10.
ICHARGE
SC
+
IDISCHARGE
−
TX
Encoding
Echo
TXI
Figure 8. Communication, Master to Slave
Communication, Slave to Master
M-BUS communication from slave to master uses bus
current modulation while the voltage remains constant. This
current modulation can be controlled from either the RX or
RXI pin as shown in Figure 10. When transmitting a space
(“0”), the current modulator will draw an additional current
from the bus. This current can be set with a programming
resistor RRIS. To achieve the space current required the
M-BUS standard, RRIS should be 100 W. A simplified
schematic of the transmitter is shown in Figure 11.
Communication, Master to Slave
M-BUS communication from master to slave is based on
voltage level signaling. To differentiate between master
signaling and voltage drop caused by the signaling of
another slave over cabling resistance, etc., the mark level
VBUS, MARK is stored, and only when the bus voltage drops
to less than VT will the NCN5150 detect communication. A
simplified schematic of the receiver is shown in Figure 8.
The received data is transmitted on the pins TX and TXI, as
shown in the waveforms of Figure 7.
An external capacitor must be connected to the SC pin to
store the mark voltage level. This capacitor is charged to VB.
Discharging of this capacitor is typically 40x slower, so that
the voltage on SC drops only a little during the time the
master is transmitting a space. The value of CSC must be
chosen it the range of 100 nF−330 nF.
Figure 9. Typical Relationship between RIS and
Current Modulation Level
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NCN5150
Because the M-BUS protocol is specified as half-duplex,
an echo function will cause the transmitted signal on RX or
RXI to appear on the receiver outputs TX and TXI. Should
the master attempt to send at the same time, the bitwise
added signal of both sources will appear on these pins,
resulting in invalid data.
shut down gracefully. The times ton and toff can be
approximated by the following formulas:
t on +
t off +
VRX
VIO
VIO
t
IBUS
I CC ) I DD
I STC
V STC, VDD ON
ǒVSTC, Clamp * VSTC, VDD OFFǓ
(eq. 1)
(eq. 2)
Where ICC is the internal current consumption of the
NCN5150 and IDD is the current consumed by external
circuits drawn from either VDD or STC.
These formulas can be used to dimension the value of the
bulk CSTC needed, taking into account that the M-BUS
standard requires ton to be less than 3 s.
For certain applications where the power drawn from the
bus is not used in external circuits, the storage capacitor
value can be much lower. The NCN5150 requires a
minimum STC capacitance of 10 mF to ensure that the bus
current regulation is stable under all conditions.
t
VRXI
C STC
C STC
ISPACE = IMARK + 15 mA
IMARK = N unit loads
t
VBUS
Figure 10. Communication, Slave to Master
VB = VSTC + 0.6
VB = VB, MIN
VIO_BUF
t
VSTC
Echo
VSTC, CLAMP
VSTC, VDD ON
VSTC, VDD OFF
RX
Decoding
VB
ton
t
RXI
VVS
Enable
+
−
VSTC, CLAMP
t
VDD
3.3 V
RIS
t
VPFb
VIO
toff
Figure 11. Communication, Slave to Master
t
Figure 12. Power-on and Power-off
Power On/Off Sequence
The power-on and power-off sequence of the NCN5150
is shown in Figure 12. Shown also in Figure 12 is the
operation of the PFb pin. This pin is used to give an early
warning to the microcontroller that the bus power is
collapsing, allowing the microcontroller to save its data and
Thermal Shutdown
The NCN5150 includes a thermal shutdown function that
will disable the transmitter when the junction temperature of
the IC becomes too hot. The thermal protection is only active
when the slave is transmitting a space to the master.
Table 10. ORDERING INFORMATION
Device
NCN5150DG
NCN5150DR2G
NCN5150MNTWG
Package
Shipping†
SOIC16
(Pb-free)
48 Units / Tube
NQFP20, 4x4
(Pb-free)
3,000 / Tape & Reel
2,500 / Tape & Reel
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging
Specifications Brochure, BRD8011/D.
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10
NCN5150
PACKAGE DIMENSIONS
QFN20, 4x4, 0.5P
CASE 485E
ISSUE B
A
B
D
PIN ONE
REFERENCE
2X
0.15 C
ÉÉÉ
ÉÉÉ
ÉÉÉ
ÇÇ
ÉÉ
EXPOSED Cu
E
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. DIMENSION b APPLIES TO PLATED TERMINAL
AND IS MEASURED BETWEEN 0.15 AND 0.30 MM
FROM THE TERMINAL TIP.
4. COPLANARITY APPLIES TO THE EXPOSED PAD
AS WELL AS THE TERMINALS.
ÉÉ
ÉÉ
ÇÇ
A3
MOLD CMPD
A1
DETAIL B
OPTIONAL CONSTRUCTIONS
2X
0.15 C
L
L
TOP VIEW
(A3)
DETAIL B
L1
A
0.10 C
DETAIL A
OPTIONAL CONSTRUCTIONS
0.08 C
A1
SIDE VIEW
C
DIM
A
A1
A3
b
D
D2
E
E2
e
K
L
L1
MILLIMETERS
MIN
MAX
0.80
1.00
--0.05
0.20 REF
0.20
0.30
4.00 BSC
2.60
2.90
4.00 BSC
2.60
2.90
0.50 BSC
0.20 REF
0.35
0.45
0.00
0.15
SEATING
PLANE
SOLDERING FOOTPRINT*
0.10 C A B
D2
DETAIL A
20X
4.30
6
20X
0.58
L
2.88
0.10 C A B
11
E2
1
1
20
K
20X
e
2.88 4.30
b
0.10 C A B
0.05 C
NOTE 3
PKG
OUTLINE
BOTTOM VIEW
20X
0.35
0.50
PITCH
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
11
NCN5150
PACKAGE DIMENSIONS
SOIC−16
CASE 751B−05
ISSUE K
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSIONS A AND B DO NOT INCLUDE MOLD
PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.15 (0.006) PER SIDE.
5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR PROTRUSION
SHALL BE 0.127 (0.005) TOTAL IN EXCESS OF THE D
DIMENSION AT MAXIMUM MATERIAL CONDITION.
−A−
16
9
1
8
−B−
P
8 PL
0.25 (0.010)
B
M
S
DIM
A
B
C
D
F
G
J
K
M
P
R
G
R
K
F
X 45 _
C
−T−
SEATING
PLANE
J
M
D
MILLIMETERS
MIN
MAX
9.80
10.00
3.80
4.00
1.35
1.75
0.35
0.49
0.40
1.25
1.27 BSC
0.19
0.25
0.10
0.25
0_
7_
5.80
6.20
0.25
0.50
INCHES
MIN
MAX
0.386
0.393
0.150
0.157
0.054
0.068
0.014
0.019
0.016
0.049
0.050 BSC
0.008
0.009
0.004
0.009
0_
7_
0.229
0.244
0.010
0.019
16 PL
0.25 (0.010)
M
T B
S
A
S
SOLDERING FOOTPRINT*
8X
6.40
16X
1.12
1
16
16X
0.58
1.27
PITCH
8
9
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.
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12
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NCN5150/D