TI AFE031AIRGZT

AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
www.ti.com
Powerline Communications
Analog Front-End
Check for Samples: AFE031
FEATURES
DESCRIPTION
• Integrated Powerline Driver with Thermal and
Overcurrent Protection
• Conforms to EN50065-1
• PRIME Certified
• Large Output Swing: 12 VPP at 1.5 A
(15-V Supply)
• Low Power Consumption: 15 mW (Receive
Mode)
• Programmable Tx and Rx Filters
• Supports EN50065 CENELEC Bands A, B, C, D
• Supports FSK, S-FSK, and OFDM
• Supports PRIME, G3, IEC 61334
• Receive Sensitivity: 20 μVRMS, Typical
• Programmable Tx/Rx Gain Control
• Four-Wire Serial Peripheral Interface
• Two Integrated Zero Crossing Detectors
• Two-Wire Transceiver Buffer
• 48-Pin QFN PowerPAD™ Package
• Extended Junction Temperature Range:
–40°C to +125°C
The AFE031 is a low-cost, integrated, powerline
communications (PLC) analog front-end (AFE) device
that is capable of capacitive- or transformer-coupled
connections to the powerline while under the control
of a DSP or microcontroller. It is ideal for driving
low-impedance lines that require up to 1.5 A into
reactive loads. The integrated receiver is able to
detect signals down to 20 μVRMS and is capable of a
wide range of gain options to adapt to varying input
signal conditions. This monolithic integrated circuit
provides high reliability in demanding powerline
communications applications.
1
234
APPLICATIONS
eMetering
Lighting
Solar
Pilot Wire
E_Rx_OUT
PA_OUT
E_Rx_IN
PA_GND
TSENSE
PA_VS
ZC_IN1
ZC_IN2
PA_ISET
REF2
REF1
DVDD
DGND
AGND1
AVDD1
AGND2
AVDD2
The AFE031 is internally protected against
overtemperature and short-circuit conditions. It also
provides an adjustable current limit. An interrupt
output is provided that indicates both current limit and
thermal limit. There is also a shutdown pin that can
be used to quickly put the device into its lowest
power state. Through the four-wire serial peripheral
interface, or SPI™, each functional block can be
enabled or disabled to optimize power dissipation.
The AFE031 is housed in a thermally-enhanced,
surface-mount PowerPAD package (QFN-48).
Operation is specified over the extended industrial
junction temperature range of –40°C to +125°C.
ZC_OUT2
ZC_OUT1
•
•
•
•
The AFE031 transmit power amplifier operates from a
single supply in the range of 7 V to 26 V. At
maximum output current, a wide output swing
provides a 12-VPP (IOUT = 1.5 A) capability with a
nominal 15-V supply. The analog and digital signal
processing circuitry operates from a single 3.3-V
power supply.
E_Tx_CLK
ZC1
Bias
E_Tx_IN
ZC2
E_Tx_OUT
Two-Wire Rx/Tx
RxPGA_1
SCLK
DI
DO
Digital Interface
(SPI)
Rx_PGA1_IN
Power
Amplifier
CS
Rx_PGA1_OUT
Rx_F_IN
DAC
SD
Tx_FLAG
Rx_FLAG
Rx_C1
Control
Register
Rx_C2
INT
Rx Filter
Rx_F_OUT
RxPGA_2
Digital-to-Analog
Converter
TxPGA
Tx Filter
Rx_PGA2_IN
Rx_PGA2_OUT
Tx_F_OUT
PA_IN
Tx_F_IN2
TX_PGA_OUT
Tx_F_IN1
Tx_PGA_IN
AFE031
1
2
3
4
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PowerPAD, C2000 are trademarks of Texas Instruments.
SPI is a trademark of Motorola, Inc.
All other trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2010–2011, Texas Instruments Incorporated
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
PACKAGE/ORDERING INFORMATION (1)
(1)
PRODUCT
PACKAGE-LEAD
PACKAGE DESIGNATOR
PACKAGE MARKING
AFE031AIRGZT
QFN-48 PowerPAD
RGZ
AFE031A
AFE031AIRGZR
QFN-48 PowerPAD
RGZ
AFE031A
For the most current package and ordering information see the Package Option Addendum at the end of this document, or visit the
device product folder at www.ti.com.
ABSOLUTE MAXIMUM RATINGS (1)
Over operating free-air temperature range (unless otherwise noted).
Supply voltage, PA_VS
VALUE
UNIT
+26
V
Voltage (2)
PA_GND – 0.4 to PA_VS + 0.4
V
Current (2)
±10
mA
+5.5
V
Signal input terminal, pins 13,
15, 16, 21, 23, 24, 25, 28, 32,
34, 35, 38, 39, 46
Voltage (2)
AGND – 0.4 to AVDD + 0.4
V
±10
mA
Signal input terminal, pin 27
Voltage limit
±10
V
Signal input terminal, pin 10
Current limit
±10
mA
+5.5
V
Signal input terminal,
pins 18,19
Supply voltage, AVDD
Current
(2)
Supply voltage, DVDD
Signal input terminal, pins 3,
4, 6, 7, 8
Signal output terminal, pins 5,
9, 14, 17, 20, 22, 26, 31, 33,
36, 37, 47, 48
Voltage
(2)
DGND – 0.4 to DVDD + 0.4
V
±10
mA
Current (2)
Current (2)
Continuous
Output short-circuit (PA), pins 42,43 (3) (4)
Continuous
Operating temperature, TA (4)
–40 to +150
°C
Storage temperature, TA
–55 to +150
°C
Junction temperature, TJ
+150
°C
Human body model (HBM)
3000
V
Machine model (MM)
200
V
Charged device model (CDM)
500
V
ESD ratings
(1)
(2)
(3)
(4)
Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may
degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those specified is not implied.
Input terminals are diode-clamped to the power-supply rails. Input signals that can swing more than 0.4 V beyond the supply rails should
be current limited to 10 mA or less. Output terminals are diode-clamped to the power-supply rails. Output signals that can swing more
than 0.4 V beyond the supply rails should be current limited to 10 mA or less.
Short-circuit to ground.
The AFE031 automatically goes into shutdown at junction temperatures that exceed +150°C.
2
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Transmitter (Tx)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Tx_DAC
Output range
AVDD – 0.1
GND + 0.1
Resolution
V
3.2
mV
Second harmonic distortion
–73
dB
Third harmonic distortion
–56
dB
Fourth harmonic distortion
–94
dB
1.5
MSPS
Total harmonic distortion at
62.5 kHz (1)
1,024 steps, 10-bit DAC
THD
Data rate
Tx_PGA
Input
GND – 0.1
Input voltage range
Input resistance
RI
AVDD + 0.1
V
G = 1 V/V
58
kΩ
G = 0.707 V/V
68
kΩ
G = 0.5 V/V
77
kΩ
G = 0.25 V/V
92
kΩ
Frequency Response
DAC mode enabled
Bandwidth
BW
G = 1 V/V
8
MHz
G = 0.707 V/V
9
MHz
G = 0.5 V/V
10
MHz
G = 0.25 V/V
12
MHz
RLOAD = 10 kΩ, connected to AVDD/2
10
Sourcing
25
mA
Sinking
25
mA
f = 100 kHz
1
Ω
Output
Voltage output swing from
AGND or AVDD
Maximum continuous
current, dc
Output resistance
VO
IO
RO
100
mV
Gain
Gain error
Gain error drift
(1)
For all gains
TJ = –40°C to +125°C
–1
±0.1
6
+1
%
ppm/°C
Total harmonic distortion measured at output of Tx_PGA configured in a gain of 1 V/V with an amplitude of 3 VPP, at a 1-MHz sample
rate.
3
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
www.ti.com
ELECTRICAL CHARACTERISTICS: Transmitter (Tx) (continued)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Tx_FILTER
Input
GND – 0.1
Input voltage range
Input resistance
(Tx_F_IN1 and Tx_F_IN2)
RI
AVDD + 0.1
V
43
kΩ
95
kHz
Frequency Response
CENELEC A Mode
–3 dB
Passband frequency
–50
Stop band attenuation
Stop band frequency
Filter gain
–60
dB
910
kHz
0
dB
145
kHz
CENELEC B/C/D Modes
–3 dB
Passband frequency
–50
Stop band attenuation
Stop band frequency
Filter gain
–60
dB
870
kHz
0
dB
Output
Voltage output swing from
AGND or AVDD
Maximum continuous
current, dc
Output resistance
VO
IO
RO
RLOAD = 10 kΩ, connected to AVDD/2
10
100
mV
Sourcing
25
mA
Sinking
25
mA
f = 100 kHz
1
Ω
Transmitter Noise
Integrated noise at PA output (2)
(2)
CENELEC Band A
(40 kHz to 90 kHz)
Noise-reducing capacitor = 1 nF from
pin 19 to ground
435
μVRMS
CENELEC Bands B/C/D
(95 kHz to 140 kHz)
Noise-reducing capacitor = 1 nF from
pin 19 to ground
460
μVRMS
Includes DAC, Tx_PGA, Tx_Filter, PA, and REF1 bias generator.
4
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Power Amplifier (PA)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Input
Input resistance
PA_VS +
0.1
GND – 0.1
Input voltage range
RI
V
20
kΩ
670
kHz
Frequency Response
Bandwidth
BW
Slew rate
SR
ILOAD = 0
Full-power bandwidth
AC PSRR
10-V step
19
V/μs
VOUT = 10 VPP
300
kHz
f = 50 kHz
14
dB
IO = 300 mA, sourcing
0.3
1
V
IO = 1.5 A, sourcing
1.7
2
V
IO = 300 mA, sinking
0.3
1
V
1.3
2
V
Output
Voltage output swing from
PA_VS
Voltage output swing from
PA_Gnd
Maximum continuous current, dc
VO
VO
Maximum peak current, ac
Output resistance
IO = 1.5 A, sinking
IO
7.5 kΩ connected to PA_ISET
1.5
A
TJ = –40°C to +125°C; f = 50 kHz
1.7
A
IO = 1.5 A
0.1
Ω
RO
PA disabled
Output impedance
f = 100 kHz, REF1 enabled
145 ll 120
Current limit equation
Solved for RSET (Current Limit)
Gain
Nominal gain
kΩ ll pF
±0.4 to ±1.5
Output current limit range
A
ILIM = 20 kΩ • [1.2 V/(RSET + 5 kΩ)]
A
RSET = [(20 kΩ • 1.2 V/ILIM) – 5 kΩ]
Ω
RLOAD = 1 kΩ
G
6.5
–1
Gain error
TJ = –40°C to +125°C
Gain error drift
0.1
±1
V/V
+1
%
ppm/°C
TSENSE Diode
Diode ideality factor
η
1.033
Thermal Shutdown
Junction temperature at shutdown
Hysteresis
Return to normal operation
+160
°C
15
°C
+145
°C
5
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
www.ti.com
ELECTRICAL CHARACTERISTICS: Receiver (Rx)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Rx PGA1
Input
Input voltage range
Input resistance
RI
10
VPP
G = 2 V/V
10
kΩ
G = 1 V/V
15
kΩ
G = 0.5 V/V
20
kΩ
G = 0.25 V/V
24
kΩ
G = 2 V/V
6
MHz
Frequency Response
Bandwidth
BW
G = 1 V/V
10
MHz
G = 0.5 V/V
13
MHz
G = 0.25 V/V
15
MHz
RLOAD = 6 kΩ, connected to AVDD/2
10
Sourcing
25
mA
Sinking
25
mA
G = 1, f = 100 kHz
1
Ω
Output
Voltage output swing from
AGND or AVDD
Maximum continuous current, dc
Output resistance
VO
IO
RO
100
mV
Gain
Gain error
G = 0.25 V/V
–1
±0.1
+1
%
G = 0.5 V/V
–1
±0.1
+1
%
G = 1 V/V
–1
±0.1
+1
%
G = 2 V/V
–2
±0.2
+2
%
TJ = –40°C to +125°C
Gain error drift
1
ppm/°C
Rx Filter
Input
GND – 0.1
Input voltage range
Input resistance
RIN
AVDD + 0.1
V
6
kΩ
90
kHz
Frequency Response
CENELEC A Mode
Rx_C1 = 680 pF, Rx_C2 = 680 pF
Passband frequency
–3 dB
–25
Stop band attentuation
Stop band frequency
Filter gain
CENELEC B/C/D Modes
–33
dB
270
kHz
0
dB
145
kHz
Rx_C1 = 270 pF, Rx_C2 = 560 pF
–3 dB
Passband frequency
–25
Stop band attentuation
Stop band frequency
Filter gain
–35
dB
350
kHz
0
dB
Output
Voltage output swing from
AGND or AVDD
Maximum continuous current, dc
Output resistance
VO
IO
RO
RLOAD = 10 kΩ, connected to AVDD/2
10
Sourcing
25
mA
Sinking
25
mA
f = 100 kHz
5
Ω
6
100
mV
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Receiver (Rx) (continued)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Rx PGA2
Input
GND – 0.1
Input voltage range
Input impedance
AVDD + 0.1
V
G = 64 V/V
1.7
kΩ
G = 16 V/V
6.3
kΩ
G = 4 V/V
21
kΩ
G = 1 V/V
53
kΩ
G = 64 V/V
300
kHz
G = 16 V/V
800
kHz
G = 4 V/V
1.4
MHz
G = 1 V/V
4
MHz
RLOAD = 10 kΩ, connected to AVDD/2
10
Sourcing
25
mA
Sinking
25
mA
G = 1, f = 100 kHz
1
Ω
RI
Frequency Response
Bandwidth
BW
Output
Voltage output swing from
AGND or AVDD
Maximum continuous current, dc
Output impedance
VO
IO
RO
100
mV
Gain
Gain error
G = 1 V/V
–2
±1
2
%
G = 4 V/V
–2
±1
2
%
G = 16 V/V
–2
±1
2
%
G = 64 V/V
–4
±1
4
%
TJ = –40°C to +125°C
6
ppm/°C
CENELEC Band A
(40 kHz to 90 kHz)
Noise-reducing capacitor = 1 μF from
pin 28 to ground
14
μVRMS
CENELEC Bands B/C/D
(95 kHz to 140 kHz)
Noise-reducing capacitor = 1 μF from
pin 28 to ground
11
μVRMS
Gain error drift
Rx Sensitivity
Integrated noise, RTI (1)
(1)
Includes Rx PGA1, Rx_Filter, Rx PGA2, and REF2 bias generator.
7
Copyright © 2010–2011, Texas Instruments Incorporated
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SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Digital
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Digital Inputs (SCLK, DIN, CS, DAC, SD)
0 ≤ VIN ≤ DVDD
Leakage input current
–1
0.01
1
μA
Input logic levels
High-level input voltage
VIH
Low-level input voltage
VIL
0.7 • DVDD
SD > 0.7 • DVDD
SD pin high
V
0.3 • DVDD
SD < 0.3 • DVDD
AFE031 in normal operation
DAC pin high
DAC > 0.7 • DVDD
SPI access to DAC Registers
DAC pin low
DAC < 0.3 • DVDD
SPI access to Command and Data
Registers
SD pin low
V
AFE031 in shutdown
Digital Outputs (DO, ZC_OUT)
High-level output voltage
VO
H
Low-level output voltage
VOL
IOH = 3 mA
DVDD – 0.4
DVDD
V
IOL = –3 mA
GND
GND + 0.4
V
1
μA
Digital Outputs (INT, Tx_Flag, Rx_Flag)
High-level output current
IOH
VOH = 3.3 V
Low-level output voltage
VOL
IOL = 4 mA
Low-level output current
IOL
VOL = 400 mV
0.4
4
V
mA
INT sink current < 1 μA
Normal operation
μs
INT pin low (open drain) (1)
INT < 0.4 V
Indicates an interrupt has occurred
μs
Tx_Flag high (open drain)
Tx_Flag sink current < 1 μA
Indicates Tx block is not ready
μs
Tx_Flag low (open drain)
Tx_Flag < 0.4 V
Indicates Tx block is ready
μs
Rx_Flag high (open drain)
Rx_Flag sink current < 1 μA
Indicates Rx block is not ready
μs
Rx_Flag low (open drain)
Rx_Flag < 0.4 V
Indicates Rx block is ready
μs
INT pin high (open drain)
DIGITAL TIMING
Gain Timing
0.2
μs
Enable time
4.0
μs
Disable time
2.0
μs
50
μs
Gain select time
Shutdown Mode Timing
POR Timing
Power-On Reset power-up time
(1)
DVDD ≥ 2 V
When an interrupt is detected (INT pin low), the contents of the I_Flag and T_Flag Registers can be read to determine the reason for the
interrupt.
8
Copyright © 2010–2011, Texas Instruments Incorporated
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AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Two-Wire Interface
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
TWO-WIRE TRANSMITTER
Frequency range (1)
50
Leakage input current
(E_Tx_In, E_Tx_Clk)
0 ≤ VIN ≤ DVDD
–1
kHz
0.01
1
μA
Input logic levels (E_Tx_In, E_Tx_Clk)
High-level input voltage
VIH
Low-level input voltage
VIL
0.7 • DVDD
V
0.3 • DVDD
V
Output logic levels (E_Tx_Out)
VO
High-level output voltage
H
Low-level output voltage
VOL
IOH = 3 mA
AVDD – 0.4
AVDD
V
IOL = –3 mA
GND
GND + 0.4
V
TWO-WIRE RECEIVER
Gain
–4.5
dB
Frequency range
300
kHz
Max sink current
25
mA
Max source current
25
mA
Input terminal offset
–100
Referenced to VAVDD/2
10
Input impedance
100
78
mV
kΩ
ZERO CROSSING DETECTOR
Input voltage range
AVDD – 0.4
Input current range
–10
AVDD + 0.4
+10
Input capacitance
3
V
mA
pF
Rising threshold
0.45
0.9
1.35
V
Falling threshold
0.25
0.5
0.75
V
Hysteresis
0.20
0.4
0.60
Jitter
(1)
50 Hz, 240 VRMS
10
V
ns
The two-wire transmitter circuit is tested at Tx_CLK = 10 MHz.
ELECTRICAL CHARACTERISTICS: Internal Bias Generator
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
REF1 (Pin 19)
Bias voltage
Input resistance
RI
PA_VS/2
V
4
kΩ
Turn-on time
Noise-reducing capacitor = 1 nF from
pin 19 to ground
20
ms
Turn-off time
Noise-reducing capacitor = 1 nF from
pin 19 to ground
20
ms
REF2 (Pin 28)
Bias voltage
Input resistance
RI
VAVDD/2
V
4
kΩ
Turn-on time
Noise-reducing capacitor = 1 μF from
pin 28 to ground
20
ms
Turn-off time
Noise-reducing capacitor = 1 μF from
pin 28 to ground
20
ms
9
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
AFE031
SBOS531B – AUGUST 2010 – REVISED SEPTEMBER 2011
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ELECTRICAL CHARACTERISTICS: Power Supply
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
AFE031
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Operating Supply Range
Power amplifier supply voltage
PA_VS
+7
+26
V
Digital supply voltage
DVDD
+3.0
+3.6
V
Analog supply voltage
AVDD
+3.0
+3.6
V
Quiescent Current
Power amplifier current
Digital supply current
SD pin low
IO = 0, PA = On (1)
IQPA_VS
mA
10
μA
1.2
mA
Rx configuration (4)
5
μA
All blocks disabled
Analog supply current
61
Tx configuration (3)
IO = 0, PA = Off
IQDVDD
49
(2)
(5)
μA
5
Tx configuration (3)
2.8
3.7
mA
Rx configuration (4)
3.6
5.3
mA
All blocks disabled (5)
30
IQAVDD
μA
Shutdown (SD)
PA_VS
SD pin high
75
150
μA
Digital supply voltage
DVDD
SD pin high
5
10
μA
Analog supply voltage
AVDD
SD pin high
15
40
μA
+125
°C
Power amplifier supply voltage
Temperature
–40
Specified range
(1)
(2)
(3)
(4)
(5)
Enable1 Register = 00100011, Enable2 Register = 00001110.
Enable1 Register = 00000100, Enable2 Register = 00000110.
In the Tx configuration, the following blocks are enabled: DAC, Tx, PA, REF1, and REF2. All other blocks are disabled. Enable1
Register = 00100011, Enable2 Register = 00001110.
In the Rx configuration, the following blocks are enabled: Rx, REF1, and REF2. All other blocks are disabled. Enable1 Register =
00000100, Enable2 Register = 00000110.
Enable1 Register = 00000000, Enable2 Register = 00000000.
THERMAL INFORMATION
AFE031
THERMAL METRIC (1)
RGZ (QFN)
UNITS
48 PINS
θJA
Junction-to-ambient thermal resistance
27.8
θJCtop
Junction-to-case (top) thermal resistance
12.1
θJB
Junction-to-board thermal resistance
7.5
ψJT
Junction-to-top characterization parameter
0.4
ψJB
Junction-to-board characterization parameter
7.4
θJCbot
Junction-to-case (bottom) thermal resistance
1.7
(1)
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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SPI TIMING REQUIREMENTS
PARAMETER
CONDITION
MIN
TYP
Input capacitance
MAX
1
Input rise/fall time
UNIT
pF
tRFI
CS, DIN, SCLK
2
ns
Output rise/fall time
tRFO
DOUT
10
ns
CS high time
tCSH
CS
20
ns
SCLK edge to CS fall setup time
tCS0
10
ns
CS fall to first SCLK edge setup time
tCSSC
10
ns
SCLK frequency
fSCLK
20
MHz
SCLK high time
tHI
20
ns
SCLK low time
tLO
20
ns
tSCCS
10
ns
tCS1
10
ns
DIN setup time
tSU
10
ns
DIN hold time
tHD
5
ns
SCLK last edge to CS rise setup time
CS rise to SCLK edge setup time
SCLK to DOUT valid propagation delay
tDO
20
ns
CS rise to DOUT forced to Hi-Z
tsoz
20
ns
TIMING DIAGRAMS
tCSH
CS
tCSSC
tSCCS
tLO
tCS1
tCS0
tHI
SCLK
tSU
tHD
1/fSCLK
DIN
tDO
tSOZ
Hi-Z
Hi-Z
DOUT
Figure 1. SPI Mode 0,0
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tCSH
CS
tCSSC
tSCCS
tHI
tCS1
tCS0
tLO
SCLK
tSU
tHD
1/fSCLK
DIN
tSOZ
tDO
Hi-Z
Hi-Z
DOUT
Figure 2. SPI Mode 1,1
CS
W0
SDI
SDO
W1
XX
W3
W2
XX
XX
XX
W - Command of Write Register N
XX - Don’t care; undefined.
Figure 3. Write Operation in Stand-Alone Mode
CS
SDI
SDO
R0
R1
D0
XX
R2
D1
R3
D2
Any Command
D3
R - Command of Read Register N Read
D - Data from Register N
XX - Don’t care; undefined.
Figure 4. Read Operation in Stand-Alone Mode
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DEVICE INFORMATION
PIN ASSIGNMENTS
Rx_FLAG
Tx_FLAG
PA_ISET
PA_VS1
PA_VS2
PA_OUT1
PA_OUT2
PA_GND1
PA_GND2
ZC_IN1
ZC_IN2
ZC_OUT1
48
47
46
45
44
43
42
41
40
39
38
37
RGZ PACKAGE
QFN-48
(TOP VIEW)
DGND
1
36
ZC_OUT2
DVDD
2
35
E_Tx_CLK
SCLK
3
34
E_Tx_IN
DIN
4
33
E_Tx_OUT
DOUT
5
32
E_Rx_IN
CS
6
31
E_Rx_OUT
Thermal Pad
24
Rx_C1
Rx_F_IN
23
25
Rx_C2
12
22
AGND1
Rx_F_OUT
Rx_PGA1_OUT
21
26
Rx_PGA2_IN
11
20
AVDD1
Rx_PGA2_OUT
Rx_PGA1_IN
19
27
REF1
TSENSE
18
REF2
PA_IN
28
10
17
9
Tx_F_OUT
INT
16
AGND2
Tx_F_IN2
29
15
8
Tx_F_IN1
SD
14
AVDD2
Tx_PGA_OUT
30
13
7
Tx_PGA_IN
DAC
NOTE: Exposed thermal pad is connected to ground.
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PIN DESCRIPTIONS
AFE031
PIN NO.
NAME
1
DGND
Digital ground
DESCRIPTION
2
DVDD
Digital supply
3
SCLK
SPI serial clock
4
DIN
SPI digital input
5
DOUT
6
CS
7
DAC
DAC mode select
8
SD
System shutdown
9
INT
Interrupt on overcurrent or thermal limit
10
TSENSE
11
AVDD1
Analog lupply
12
AGND1
Analog ground
13
Tx_PGA_IN
Transmit PGA lnput
14
Tx_PGA_OUT
Transmit PGA lutput
15
Tx_F_IN1
Transmit filter input 1
16
Tx_F_IN2
Transmit filter input 2
17
Tx_F_OUT
Transmit filter output
18
PA_IN
Power Amplifier input
19
REF1
Power Amplifier noise reducing capacitor
20
Rx PGA2_OUT
21
Rx PGA2_IN
22
Rx_F_OUT
23
Rx_C2
Receiver external frequency select
24
Rx_C1
Receiver external frequency select
25
Rx_F_IN
26
Rx PGA1_OUT
27
Rx PGA1_IN
SPI digital output
SPI digital chip select
Temp sensing diode (anode)
Receiver PGA(2) output
Receiver PGA(2) input
Receiver filter output
Receiver filter input
Receiver PGA(1) output
Receiver PGA(1) input
28
REF2
29
AGND2
Receiver noise reducing capacitor
Analog ground
30
AVDD2
Analog supply
31
E_Rx_OUT
32
E_Rx_IN
33
E_Tx_OUT
34
E_Tx_IN
35
E_Tx_CLK
Two-wire transmitter clock input
36
ZC_OUT2
Zero crossing detector output
37
ZC_OUT1
Zero crossing detector output
38
ZC_IN2
Zero crossing detector input
39
ZC_IN1
Zero crossing detector input
40
PA_GND2
Power Amplifier ground
41
PA_GND1
Power Amplifier ground
42
PA_OUT2
Power Amplifier output
43
PA_OUT1
Power Amplifier output
44
PA_VS2
Power Amplifier supply
45
PA_VS1
Power Amplifier supply
46
PA_ISET
Power Amplifier current limit set
47
Tx_FLAG
Transmitter ready flag
48
Rx_FLAG
Receiver ready flag
Two-wire receiver output
Two-wire receiver input
Two-wire transmitter output
Two-wire transmitter input
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DVDD
DGND
AGND1
AVDD1
AGND2
AVDD2
E_Rx_OUT
E_Rx_IN
PA_OUT
TSENSE
PA_GND
PA_VS
PA_ISET
ZC_IN1
ZC_IN2
ZC_OUT2
ZC_OUT1
REF2
REF1
FUNCTIONAL BLOCK DIAGRAM
E_Tx_CLK
ZC1
Bias
E_Tx_IN
ZC2
E_Tx_OUT
Two-Wire Rx/Tx
RxPGA_1
SCLK
DI
DO
Digital Interface
(SPI)
Rx_PGA1_IN
Power
Amplifier
CS
Rx_PGA1_OUT
Rx_F_IN
DAC
SD
Tx_FLAG
Rx_FLAG
Rx_C1
Control
Register
Rx_C2
INT
Rx Filter
Rx_F_OUT
RxPGA_2
Digital-to-Analog
Converter
TxPGA
Tx Filter
Rx_PGA2_IN
Rx_PGA2_OUT
Tx_F_OUT
PA_IN
Tx_F_IN2
TX_PGA_OUT
Tx_F_IN1
Tx_PGA_IN
AFE031
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TYPICAL CHARACTERISTICS
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
Tx Filter GAIN vs FREQUENCY
Rx Filter GAIN vs FREQUENCY
20
20
CENELEC A
CENELEC B,C,D
0
0
−10
−10
−20
−30
−20
−30
−40
−40
−50
−50
−60
10k
100k
Frequency (Hz)
CENELEC A
CENELEC B,C,D
10
Gain (dB)
Gain (dB)
10
−60
10k
1M
100k
Frequency (Hz)
G001
Figure 5.
PA GAIN vs FREQUENCY
MAXIMUM PA OUTPUT VOLTAGE vs FREQUENCY
Maximum PA Output Voltage (VPP)
25
50
40
Gain (dB)
30
20
10
0
−10
−20
−30
100k
1M
Frequency (Hz)
20
15
10
5
0
10M
PA Supply = 24V
PA Supply = 15V
PA Supply = 12V
1k
10k
G003
Figure 7.
Tx PGA GAIN vs FREQUENCY
1M
10M
G004
Rx PGA1 GAIN vs FREQUENCY
40
Gain = 1 V/V
Gain = 0.707 V/V
Gain = 0.5 V/V
Gain = 0.25 V/V
30
20
20
10
0
−10
10
0
−10
−20
−20
−30
−30
100k
1M
Frequency (Hz)
Gain = 2 V/V
Gain = 1 V/V
Gain = 0.5 V/V
Gain = 0.25 V/V
30
Gain (dB)
Gain (dB)
100k
Frequency (Hz)
Figure 8.
40
−40
10k
G002
Figure 6.
60
−40
10k
1M
10M 20M
−40
10k
G005
Figure 9.
100k
1M
Frequency (Hz)
10M
100M
G006
Figure 10.
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TYPICAL CHARACTERISTICS (continued)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
Rx PGA2 GAIN vs FREQUENCY
TWO-WIRE RECEIVER GAIN vs FREQUENCY
20
60
Gain = 64 V/V
Gain = 16 V/V
Gain = 4 V/V
Gain = 1 V/V
50
40
0
20
Gain (dB)
Gain (dB)
30
10
10
0
−10
−20
−10
−20
−30
−30
−40
10k
100k
1M
Frequency (Hz)
10M
−40
10k
100M
100k
Frequency (Hz)
G007
Figure 11.
FILTER CUTOFF vs TEMPERATURE
Tx PGA GAIN ERROR vs TEMPERATURE
0.4
CENELEC BCD, Tx and Rx
CENELEC A, Tx and Rx
175
0.3
0.2
150
Gain Error (%)
Cutoff Frequency (kHz)
G008
Figure 12.
200
125
100
0.1
0
−0.1
−0.2
75
−0.3
50
−40 −25 −10
5
20 35 50 65 80
Junction Temperature (°C)
95
−0.4
−40 −25 −10
110 125
G009
Figure 13.
0.3
0.3
0.2
0.2
Gain Error (%)
0.4
0.1
0
−0.1
110 125
G010
0.1
0
−0.1
−0.2
−0.2
−0.3
−0.3
5
20 35 50 65 80
Junction Temperature (°C)
95
Rx PGA1 GAIN ERROR vs TEMPERATURE
0.4
−0.4
−40 −25 −10
5
20 35 50 65 80
Junction Temperature (°C)
Figure 14.
PA GAIN ERROR vs TEMPERATURE
Gain Error (%)
1M
95
110 125
−0.4
−40 −25 −10
G011
Figure 15.
5
20 35 50 65 80
Junction Temperature (°C)
95
110 125
G012
Figure 16.
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TYPICAL CHARACTERISTICS (continued)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
Rx PGA2 GAIN ERROR vs TEMPERATURE
QUIESCENT SUPPLY CURRENT vs TEMPERATURE
0.4
60
0.3
Supply Current (mA)
0.2
Gain Error (%)
PA Current (PA Enabled)
AVDD Current (RX Mode)
AVDD Current (TX Mode)
50
0.1
0
−0.1
−0.2
40
30
20
10
−0.3
−0.4
−40 −25 −10
5
20 35 50 65 80
Junction Temperature (°C)
95
0
−40 −25 −10
110 125
5
20 35 50 65 80
Junction Temperature (°C)
G013
Figure 17.
95
G014
Figure 18.
SUPPLY CURRENT (SHUTDOWN) vs TEMPERATURE
PA CURRENT LIMIT vs SUPPLY
100
3
+3σ
Typical
−3σ
All blocks disabled
2.5
60
PA Current Limit (A)
Supply Current (µA)
80
PA Current
AVDD Current
DVDD Current
40
20
2
1.5
1
0.5
0
−40 −25 −10
5
20 35 50 65 80
Junction Temperature (°C)
95
0
110 125
5
G015
Figure 19.
Tx Filter PULSE RESPONSE
15
20
25
30
RSET (kΩ)
35
40
45
50
G016
PA PULSE RESPONSE
0.2
Tx Filter CENELEC A
Tx Filter CENELEC B
0.15
0.15
0.1
0.1
0.05
0.05
Voltage (V)
Voltage (V)
10
Figure 20.
0.2
0
−0.05
0
−0.05
−0.1
−0.1
−0.15
−0.15
−0.2
110 125
−0.2
0
10 µs/div (dB)
0
G017
Figure 21.
1 µs/div (dB)
G018
Figure 22.
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TYPICAL CHARACTERISTICS (continued)
At TJ = +25°C, PA_VS = 16 V, VAVDD = VDVDD = 3.3 V, and 10 kΩ connected to PA_ISET (pin 46), unless otherwise noted.
Rx PULSE RESPONSE
0.2
Rx Filter CENELEC A
Rx Filter CENELEC B
0.15
Voltage (V)
0.1
0.05
0
−0.05
−0.1
−0.15
−0.2
0
10 µs/div (dB)
G019
Figure 23.
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APPLICATION INFORMATION
GENERAL DESCRIPTION
The AFE031 is an integrated powerline communication analog front-end (AFE) device built from a variety of
functional blocks that work in conjunction with a microcontroller. The AFE031 provides the interface between the
microcontroller and a line coupling circuit. The AFE031 delivers high performance and is designed to work with a
minimum number of external components. Consisting of a variety of functional and configurable blocks, the
AFE031 simplifies design efforts and reduces the time to market of many applications.
The AFE031 includes three primary functional blocks:
• Power Amplifier (PA)
• Transmitter (Tx)
• Receiver (Rx)
The AFE031 also consists of other support circuitry blocks that provide zero crossing detection, an additional
two-wire communications channel, and power-saving biasing blocks (see the Functional Block Diagram). All of
these functional blocks are digitally controlled by the microcontroller through the serial interface (SPI).
Figure 24 shows a typical powerline communications application system diagram. Table 1 is a complete list of
the sections within the AFE031.
C2000 MCU
AFE031
Line Coupling Interface
DAC
PGA
PA
+
N1
LPF
+
N2
Phase
Neutral
Serial
Interface
Serial
Interface
Bandpass Filter
PGA
PGA
LPF
Figure 24. Typical Powerline Communications System Diagram
Table 1. Block Descriptions
BLOCK
DESCRIPTION
PA
The PA block includes the power amplifier and associated pedestal biasing circuitry
Tx
The Tx block includes the Tx_Filter and the Tx_PGA
Rx
The Rx block includes the Rx PGA1, the Rx Filter, and the Rx PGA2
ERx
The ER block includes the two-wire receiver
ETx
The ER block includes the two-wire transmitter
DAC
The DAC block includes a digital-to-analog converter
ZC
The ZC block includes both zero crossing detectors
REF1
The REF1 block includes the internal bias generator for the PA block
REF2
The REF2 block includes the internal bias generators for the Tx, Rx, ERx, and ETx
blocks
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BLOCK DESCRIPTIONS
PA Block
The Power Amplifier (PA) block consists of a high slew rate, high-voltage, and high-current operational amplifier.
The PA is configured with an inverting gain of 6.5 V/V, has a low-pass filter response, and maintains excellent
linearity and low distortion. The PA is specified to operate from 7 V to 26 V and can deliver up to ±1.5 A of
continuous output current over the specified junction temperature range of –40°C to +125°C. Figure 25 illustrates
the PA block.
PA_VS1
PA_VS2
T_SENSE
Inside the AFE031
PA_OUT1
Power
Amplifier
PA_IN
PA_OUT2
PA_GND1
PA_GND1
PA_ISET
Figure 25. PA Block Equivalent Circuit
Connecting the PA in a typical PLC application requires only two additional components: an ac coupling
capacitor, CIN, and the current limit programming resistor, RSET. Figure 26 shows the typical connections to the
PA block.
+
PA Supply
47 mF
100 nF
PA_VS1
PA_VS2
T_SENSE
Inside the AFE031
PA_OUT1
CIN
Power
Amplifier
PA_IN
PA_OUT2
PA_GND1
PA_GND1
PA_ISET
RSET
Figure 26. Typical Connections to the PA
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The external capacitor, CIN, introduces a single-pole, high-pass characteristic to the PA transfer function;
combined with the inherent low-pass transfer function, this characteristic results in a passband response. The
value of the high-pass cutoff frequency is determined by CIN reacting with the input resistance of the PA circuit,
and can be found from Equation 1:
1
CIN =
(2 · p · 20 kW · fHP)
(1)
Where:
• CIN = external input capacitor
• fHP = desired high-pass cutoff frequency
For example, setting CIN to 3.3 nF results in a high-pass cutoff frequency of 2.4 kHz. The voltage rating for CIN
should be determined to withstand operation up to the PA power-supply voltage.
When the transmitter is not in use, the output can be disabled and placed into a high-impedance state by writing
a '0' to the PA-OUT bit in the Enable2 Register. Additional power savings can be realized by shutting down the
PA when not in use. Shutting down the PA for power savings is accomplished by writing a '0' to the PA bit in the
Enable1 Register. Shutting down the PA also results in the PA output entering a high-impedance state. When the
PA shuts down, it consumes only 2 mW of power.
The PA_ISET pin (pin 46) provides a resistor-programmable output current limit for the PA block. Equation 2
determines the value of the external RSET resistor attached to this pin.
1.2 V
- 5 kW
RSET = 20 kW ·
ILIM
(2)
(
(
Where:
• RSET = the value of the external resistor connected between pin 46 and ground.
• ILIM = the value of the desired current limit for the PA.
Note that to ensure proper design margin with respect to manufacturing and temperature variations, a 30%
increase in the value used in Equation 2 for ILIM over the nominal value of ILIM is recommended. See Figure 20,
PA Current Limit vs RSET.
Tx Block
The Tx block consists of the Tx PGA and Tx Filter. The Tx PGA is a low-noise, high-performance, programmable
gain amplifier. In DAC mode (where pin 7 is a logical '1' and Enable1 Register bit location 5 is a logical '1'), the
Tx PGA operates as the internal digital-to-analog converter (DAC) output buffer with programmable gain. In
PWM mode (where pin 7 is a logical '0' and Enable1 Register bit location 5 is a logical '0'), the Tx PGA operates
as a stand-alone programmable gain amplifier. The Tx PGA gain is programmed through the serial interface. The
Tx PGA gain settings are 0.25 V/V, 0.5 V/V, 0.707 V/V, and 1 V/V.
The Tx Filter is a unity-gain, fourth-order low-pass filter. The Tx Filter cutoff frequency is selectable between
CENELEC A or CENELEC B, C, and D modes. The Control1 Register bit location 3 setting (CA CBCD)
determines the cutoff frequency. Setting Control1 Register bit location 3 to '0' selects the CENELEC A band;
setting Control1 Register bit location 3 to '1' selects CENELEC B, C, and D bands.
The AFE031 supports both DAC inputs or PWM inputs for the Tx signal path. DAC mode is recommended for
best performance. In DAC mode, no external components in the Tx signal path are required to meet regulatory
signal emissions requirements. When in DAC mode, the AFE031 accepts serial data from the microprocessor
and writes that data to the internal DAC registers. When in DAC mode (where pin 7 is a logical '1' and Enable1
Register bit location 5 is a logical '1'), the Tx PGA output must be directly coupled to the Tx_FIN1 input and the
unused Tx_FIN2 input must be grounded.
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The proper connections for the Tx signal path for DAC mode operation are shown in Figure 27. Operating in
DAC mode results in the lowest distortion signal injected onto the ac mains. No additional external filtering
components are required to meet CENELEC requirements for A, B, C or D bands when operating in DAC mode.
Inside the AFE031
MCU
SCLK
PA_OUT1
DIN
SPI
DOUT
DAC
PGA
PA
LPF
PA_OUT2
CS
Tx_PGA_
OUT
Tx_F_
IN1
Tx_F_
IN2
Tx_F_
OUT
PA_IN
Tx_PGA_IN
C
C=
(1)
1
Note (1)
2·p·f·22 kW
For capacitor value C, f is the desired lower cutoff frequency and 22 kΩ is the PA input resistance.
Figure 27. Recommended Tx Signal Chain Connections Using DAC Mode
In PWM mode (where pin 7 is a logical '0' and Enable1 Register bit location 5 is a logical '0'), the microprocessor
general-purpose input/output (GPIO) can be connected directly to either one of the Tx Filter inputs; the unused
input should remain unconnected. A lower distortion PWM signal generated from two PWM signals shifted in
phase by 90 degrees can be also be input to the Tx Filter through the use of both inputs. Figure 28 and
Figure 29 show the proper connections for single PWM and dual PWM operating modes, respectively.
Inside the AFE031
MCU
Tx_F_IN1
PA_OUT1
GPIO
Tx_F_IN2
PGA
LPF
PA
PA_OUT2
Note (1)
Tx_F_OUT
Tx_PGA_ Tx_PGA_
IN
OUT
PA_IN
C
C=
(1)
Leave unused Tx Filter input unconnected.
(2)
For capacitor value C, f is the desired lower cutoff frequency and 22 kΩ is the PA input resistance.
1
Note (2)
2·p·f·22 kW
Figure 28. Recommended Tx Signal Chain Connections in PWM Mode Using One PWM Signal
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Note (1)
Inside the AFE031
MCU
43 kW
Tx_F_IN1
PA_OUT1
GPIO
PGA
LPF
Tx_F_IN2
PA
GPIO
PA_OUT2
43 kW
Tx_F_OUT
Tx_PGA_ Tx_PGA_
IN
OUT
PA_IN
C
C=
1
Note (2)
2·p·f·22 kW
(1)
When using both Tx Filter inputs, use 43-kΩ resistors to match the input resistance for best frequency response.
(2)
For capacitor value C, f is the desired lower cutoff frequency and 22 kΩ is the PA input resistance.
Figure 29. Recommended Tx Signal Chain Connections in PWM Mode Using Two PWM Signals
In PWM mode, there is inherently more distortion from the PWM signal than from the internal DAC. To achieve
the best results in PWM mode, add passive RC filters to increase the low-pass filtering. Figure 30 and Figure 31
illustrate the recommended locations of these RC filters.
Inside the AFE031
MCU
Tx_F_IN1
PA_OUT1
GPIO
Tx_F_IN2
PGA
LPF
PA
PA_OUT2
Note (1)
Tx_F_OUT
510 W
Tx_PGA_ Tx_PGA_
OUT
IN
PA_IN
510 W
C
C
C=
C
1
Note (3)
2·p·f·22 kW
Note (2)
(1)
Leave unused Tx Filter input unconnected.
(2)
Refer to Table 2.
(3)
For capacitor value C, f is the desired lower cutoff frequency and 22 kΩ is the PA input resistance.
Figure 30. Recommended Tx Signal Chain Connections in PWM Mode
Using One PWM Signal and Additional RC Filters
24
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Note (1)
Inside the AFE031
MCU
43 kW
Tx_F_IN1
PA_OUT1
GPIO
Tx_F_IN2
PGA
LPF
PA
GPIO
PA_OUT2
43 kW
Tx_F_OUT
510 W
Tx_PGA_ Tx_PGA_
OUT
IN
PA_IN
510 W
C
C
C
C=
1
Note (3)
2·p·f·22 kW
Note (2)
(1)
When using both Tx Filter inputs, use 43-kΩ resistors to match the input resistance for best frequency response.
(2)
Refer to Table 2.
(3)
For capacitor value C, f is the desired lower cutoff frequency and 22 kΩ is the PA input resistance.
Figure 31. Recommended Tx Signal Chain Connections in PWM Mode
Using Two PWM Signals and Additional RC Filters
For the capacitors listed in Table 2, it is recommended that these components be rated to withstand the full AVDD
power-supply voltage.
Table 2. Recommended External R and C Values to
Increase Tx Filter Response Order in PWM
Applications
FREQUENCY BAND
R (Ω)
C (nF)
SFSK: 63 kHz, 74 kHz
510
2.7
CENELEC A
510
1.5
CENELEC B, C, D
510
1
The Tx PGA and Tx Filter each have the inputs and outputs externally available in order to provide maximum
system design flexibility. Care should be taken when laying out the PCB traces from the inputs or outputs to
avoid excessive capacitive loading. Keeping the PCB capacitance from the inputs to ground, or from the outputs
to ground, less than 100 pF is recommended.
Rx Block
The Rx block consists of Rx PGA1, the Rx Filter, and Rx PGA2. Both Rx PGA1 and Rx PGA2 are
high-performance programmable gain amplifiers. Rx PGA1 can be configured through the SPI to operate as
either an attenuator or in gain. The gain steps of the Rx PGA1 are 0.25 V/V, 0.5 V/V, 1 V/V, and 2 V/V. The gain
steps of the Rx PGA2 are 1 V/V, 4 V/V, 16 V/V, and 64 V/V. Configuring the Rx PGA1 as an attenuator (at gains
less than 1 V/V) is useful for applications where the presence of large interference signals are present within the
signal band. Attenuating the large interference allows these signals to pass through the analog Rx signal chain
without causing an overload; the interference signal can then be processed and removed within the
microprocessor as necessary.
25
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The Rx Filter is a very low noise, unity-gain, fourth-order low-pass filter. The Rx Filter cutoff frequency is
selectable between CENELEC A or CENELEC B, C, and D modes. The Control1 Register bit location 3 setting
(CA CBCD) determines the cutoff frequency. Setting Control1 Register bit location 3 to '0' selects the CENELEC
A band; setting Control1 Register bit location 3 to '1' selects the CENELEC B, C, and D bands. Because the Rx
Filter is a very low noise analog filter, two external capacitors are required to properly configure the Rx Filter.
Table 3 shows the proper capacitance values for CENELEC A, B, C, and D bands. Capacitor Rx C1 is connected
between pin 24 and ground, and Rx C2 is connected between pin 23 and ground. For the capacitors shown, it is
recommended that these components be rated to withstand the full AVDD power-supply voltage
Table 3. Recommended External Capacitors Required for Rx Filter
FREQUENCY BAND
Rx C1, PIN 24
Rx C2, PIN 23
CUTOFF FREQUENCY (kHz)
CENELEC A
680 pF
680 pF
90
CENELEC B, C, D
270 pF
560 pF
145
Figure 32 illustrates the recommended connections for the Rx signal chain.
Inside the AFE031
C1
330 W
From line coupling circuit
or passive bandpass filter
PGA
LPF
Rx_PGA1_
IN
C1 =
To ADC input on MCU
PGA
Rx_PGA2_
OUT
1
2·p·f·RIN,PGA1 Note (1)
Rx_C1
Rx_C2
Rx_F_
OUT
Rx_F_IN
Rx_PGA1_OUT
Rx C1
PA_IN
Rx C2
C2 =
C2
1
2·p·f·RIN,PGA2
Note (2)
See Note (3)
(1)
For capacitor value C1, f is the desired lower cutoff frequency and RIN,PGA1 is the input resistance of Rx PGA1.
(2)
For capacitor value C2, f is the desired lower cutoff frequency and RIN,PGA2 is the input resistance of Rx PGA2.
(3)
Refer to Table 3.
Figure 32. Recommended Connections for Rx Signal Chain
As Figure 33 shows, a fourth-order passive passband filter is optional but recommended for applications where
high performance is required. The external passive passband filter removes any unwanted, out-of-band signals
from the signal path, and prevents them from reaching the active internal filters within the AFE031.
R1
C1
C
L1
From line coupling circuit
To Rx PGA1
R2
C2
L2
C=
(1)
1
See Note (1)
2·p·f·RIN,PGA1
For capacitor value C, f is the desired lower cutoff frequency and RIN,PGA1 is the input resistance of Rx PGA1. Refer
to Table 3.
Figure 33. Passive Bandpass Rx Filter
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The following steps can be used to quickly design the passive passband filter. (Note that these steps produce an
approximate result.)
1. Choose the filter characteristic impedance, ZC:
– For –6-db passband attenuation: R1 = R2 = ZC
– For 0-db passband attenuation: R1 = ZC, R2 = 10 ● ZC
2. Calculate values for C1, C2, L1, and L2 using the following equations:
1
C1 = (2 · p · f · Z )
1
C
1
C2 = (2 · p · f · Z )
2
C
L1 =
ZC
(2 · p · f2)
L2 =
ZC
(2 · p · f1)
Table 4 and Table 5 shows standard values for common applications.
Table 4. Recommended Component Values for Fourth-Order Passive Bandpass Filter (0-db Passband
Attenuation)
FREQUENCY
RANGE
(kHz)
CHARACTERISTIC
IMPEDANCE
(Ω)
R1
(Ω)
R2
(Ω)
C1
(nF)
C2
(nF)
L1
(μH)
L2
(μH)
CENELEC A
35 to 95
1k
1k
10k
4.7
1.5
1500
4700
CENELEC B, C, D
95 to 150
1k
1k
10k
1.7
1
1200
1500
SFSK
63 to 74
1k
1k
10k
2.7
2.2
2200
2200
FREQUENCY BAND
Table 5. Recommended Component Values for Fourth-Order Passive Bandpass Filter (–6-db Passband
Attenuation)
FREQUENCY
RANGE
(kHz)
CHARACTERISTIC
IMPEDANCE
(Ω)
R1
(Ω)
R2
(Ω)
C1
(nF)
C2
(nF)
L1
(μH)
L2
(μH)
CENELEC A
35 to 95
1k
1k
1k
4.7
1.5
1500
4700
CENELEC B, C, D
95 to 150
1k
1k
1k
1.7
1
1200
1500
SFSK
63 to 74
1k
1k
1k
2.7
2.2
2200
2200
FREQUENCY BAND
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The Rx PGA1, Rx Filter, and Rx PGA2 components have all inputs and outputs externally available to provide
maximum system design flexibility. Care should be taken when laying out the PCB traces from the inputs or
outputs to avoid excessive capacitive loading. Keeping the PCB capacitance from the inputs to ground, or
outputs to ground, below 100 pF is recommended.
Figure 34 shows the complete Rx signal path, including the optional passive passband filter.
C1 =
1
2·p·f·RIN,PGA1
Inside the AFE031
Note (1)
R2
From line coupling
circuit
C3
C1
L1
330 W
PGA
R3
C4
L2
To ADC
input on MCU
PGA
LPF
Rx_PGA1_
IN
Rx_PGA2_
OUT
Rx_C1
Rx_PGA1_OUT
Rx_C2
Rx_F_
OUT
Rx_F_IN
Rx C1
PA_IN
Rx C2
C2
C2 =
1
2·p·f·RIN,PGA2
Note (2)
See Note (3)
(1)
For capacitor value C1,f is the desired lower cutoff frequency and RIN,PGA1 is the input resistance of Rx PGA1.
(2)
For capacitor value C2,f is the desired lower cutoff frequency and RIN,PGA2 is the input resistance of Rx PGA2.
(3)
Refer to Table 3.
Figure 34. Complete Rx Signal Path (with Optional Bandpass Filter)
DAC Block
The DAC block consists only of the 10-bit DAC. The use of the DAC is recommended for best performance. The
serial interface is used to write directly to the DAC registers when the DAC pin (pin 7) is driven high. Placing the
DAC pin into a high state configures the SPI for direct serial interface to the DAC. Use the following sequence to
write to the DAC:
• Set CS low.
• Set the DAC pin (pin 7) high.
• Write a 10-bit word to DIN. The DAC register is left-justified and truncates more than 10 bits.
• CS high updates the DAC.
Refer to Figure 35 for an illustration of this sequence.
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CS
DAC
DIN
SCLK
Time
Figure 35. Writing to the DAC Register
Table 6 lists the DAC Register configurations.
Table 6. DAC Registers
DAC PIN HIGH:
DAC REGISTER <15:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
FUNCTION
DAC<0>
0
--
W
Truncated
DAC<1>
1
--
W
Truncated
DAC<2>
2
--
W
Truncated
DAC<3>
3
--
W
Truncated
DAC<4>
4
--
W
Truncated
DAC<5>
5
--
W
Truncated
DAC<6>
6
--
W
DAC bit 0 = DAC LSB
DAC<7>
7
--
W
DAC bit 1
DAC<8>
8
--
W
DAC bit 2
DAC<9>
9
--
W
DAC bit 3
DAC<10>
10
--
W
DAC bit 4
DAC<11>
11
--
W
DAC bit 5
DAC<12>
12
--
W
DAC bit 6
DAC<13>
13
--
W
DAC bit 7
DAC<14>
14
--
W
DAC bit 8
DAC<15>
15
--
W
DAC bit 9 = DAC MSB
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REF1 and REF2 Blocks
The REF1 and REF2 blocks create midscale power-supply biasing points used internally to the AFE031. Each
reference divides its respective power-supply voltage in half with a precision resistive voltage divider. REF1
provides a PA_VS/2 voltage at the output of the PA, while REF2 provides an AVDD/2 voltage at the outputs of the
Tx PGA, Tx Filter, Rx PGA1, Rx Filter, and Rx PGA2. Each REF block has its output brought out to an external
pin that can be used for filtering and noise reduction. Figure 36 and Figure 37 show the proper connections of
the external noise-reducing capacitors. These capacitors are optional, but are recommended for best
performance.
PA_VS
Inside the AFE031
R
4 kW
REF1
R
Internal
External 1-mF
noise reduction capacitor
PA_VS
bias
2
PA_GND
Figure 36. REF1 Functional Diagram
AVDD
Inside the AFE031
R
4 kW
REF2
R
Internal
External 1-nF
noise reduction capacitor
AVDD
bias
2
AGND
Figure 37. REF2 Functional Diagram
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Zero Crossing Detector Block
The AFE031 includes two zero crossing detectors. Zero crossing detectors can be used to synchronize
communications signals to the ac line or sources of noise. Typically, in single-phase applications, only a single
zero crossing detector is used. In three-phase applications, both zero crossing detectors can be used; one
component detects phase A, and one detects phase B. Phase C zero crossings can then be inferred from the
data gathered from the other phases. Figure 38 shows the AFE031 configured for non-isolated zero crossing
detection.
+
AVDD
3.3 V
ZLLS410 or
equivalent
330 kW
330 kW
120 VAC
to 240 VAC
50/60 Hz
AVDD
330 kW
ZCIN
ZCOUT
Zero
Crossing
ZLLS410 or
equivalent
AGND
Inside the AFE031
Figure 38. Non-Isolated Zero Crossing Detection Using the AFE031
120 VAC to 240 VAC
50 Hz to 60 Hz
Non-isolated zero crossing waveforms are shown in Figure 39.
350
0
-350
ZCOUT
3.3
0.0
0
50
100
Time (5 ms/div)
Figure 39. Non-Isolated Zero Crossing Waveforms
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For maximum protection of the AFE031 against line transients, it is recommended to use Schottky diodes as
indicated in Figure 38. These diodes should limit the ZC_IN pins (pins 38 and 39) to within the maximum rating
of (AVDD + 0.4 V) and (AGND – 0.4 V). Some applications may require an isolated zero crossing detection circuit.
With a minimal amount of components, the AFE031 can be configured for isolated zero crossing detection, as
Figure 40 shows.
+
AVDD
3.3 V
AVDD
ZCIN
ZCOUT
Zero
Crossing
120 VAC
to 240 VAC
50/60 Hz
AGND
Inside the AFE031
PS2505-1A Opto Isolator
or equivalent
Figure 40. Isolated Zero Crossing Detection Using the AFE031
120 VAC to 240 VAC
50 Hz to 60 Hz
Isolated zero crossing waveforms are shown in Figure 41.
350
0
-350
ZCOUT
3.3
0.0
0
50
100
Time (5 ms/div)
Figure 41. Isolated Zero Crossing Waveforms
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ETx and ERx Blocks
The AFE031 contains a two-wire transmitter block, ETx, and a two-wire receiver block, ERx. These blocks
support communications that use amplitude shift keying (ASK) with on-off keying (OOK) modulation.
The ETx block is a gated driver that allows for transmission of a carrier input signal and modulating input signal.
For typical applications, a 50-kHz square wave carrier signal is applied to E_Tx_Clk while the modulating signal
is applied to E_Tx_In. The output (E_Tx_Out) is then in a high-impedance state when E_Tx_In is '1'. Figure 42
shows the relationship between E_Tx_Clk, E_Tx_In, and E_Tx_Out.
3.3
E_Tx_Clk
0
3.3
E_Tx_In
0
3.3
E_Tx_Out
0
Time (s)
Figure 42. ETx Block Transfer Function
The ERx Block consists of a low-pass analog filter configured in an inverting gain of –4.5 db. This block, along
with an external capacitor, can be used to create a passband filter response as shown in Figure 43.
Gain (dB)
0
-20
High-pass cutoff determined by:
fHP =
1
2p·RIN·CEXT
where:
RIN = Input resistance of ERx = 78 kW
CEXT = External capacitance
-40
10
100
1k
10k
100k
1M
10M
100M
Frequency (Hz)
Figure 43. ERx Block Frequency Response
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The E_Rx_Out pin can be directly connected to either an available analog-to-digital converter (ADC) input or
GPIO on the host microcontroller. Figure 44 illustrates a typical two-wire application for ETx and ERx.
AFE031
Internal Configuration
E_Tx_In
TMS320F28x
E_Tx_Out
GPIO
Flexible PLC
Software Engine
CEXT
E_Rx_In
E_Tx_CLK
GPIO
+
N1
+
N2
Two-Wire Bus
E_Rx_Out
GND
GPIO
Figure 44. Typical Two-Wire Application for ETx and ERx
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SERIAL INTERFACE
The AFE031 is controlled through a serial interface that allows read/write access to the control and data
registers. A host SPI frame consists of a R/W bit, a 6-bit register address, and eight data bits. Data are shifted
out on the falling edge of SCLK and latched on the rising edge of SCLK. Refer to the Timing Diagrams for a valid
host SPI communications protocol. Table 7 through Table 16 show the complete register information.
Table 7. Data Register
ADDRESS
DEFAULT
ENABLE1
REGISTER
0x01
0x00
Block enable or disable
FUNCTION
GAIN SELECT
0x02
0x32
Rx and Tx gain select
ENABLE2
0x03
0x00
Block enable or disable
CONTROL1
0x04
0x00
Frequency select and calibration, Tx and Rx status
CONTROL2
0x05
0x01
Interrupt enable
RESET
0x09
0x00
Interrupt status and device reset
DIE_ID
0x0A
0x00
Die name
REVISION
0x0B
0x02
Die revision
Table 8. Command Register
LOCATION
(15 = MSB)
R/W
8
W
Register address bit
ADDR9
9
W
Register address bit
ADDR10
10
W
Register address bit
ADDR11
11
W
Register address bit
ADDR12
12
W
Register address bit
ADDR13
13
W
Register address bit
ADDR14
14
W
Register address bit
R/W
15
W
Read/write: read = 1, write = 0
BIT NAME
ADDR8
FUNCTION
Table 9. Enable1 Register: Address 0x00
Default: 0x00
Enable1 Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
FUNCTION
PA
0
0
R/W
This bit is used to enable/disable the PA Block.
0 = disabled, 1 = enabled.
TX
1
0
R/W
This bit is used to enable/disable the Tx Block.
0 = disabled, 1 = enabled.
RX
2
0
R/W
This bit is used to enable/disable the Rx Block.
0 = disabled, 1 = enabled.
ERX
3
0
R/W
This bit is used to enable/disable the ERx Block.
0 = disabled, 1 = enabled.
ETX
4
0
R/W
This bit is used to enable/disable the ETx Block.
0 = disabled, 1 = enabled.
DAC
5
0
R/W
This bit is used to enable/disable the DAC Block.
0 = DAC disabled; switch is connected to Tx_PGA_IN pin.
1 = DAC enabled; switch is connected to DAC output.
--
6
0
--
Reserved
--
7
0
--
Reserved
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Table 10. Gain Select Register: Address 0x02
Default: 0x32
Gain Select Register <7:0>
BIT NAME
RX1G-0,
RX1G-1
RX2G-0,
RX2G-1
TXG-0,
TXG-1
LOCATION
(0 = LSB)
0, 1
2, 3
DEFAULT
0, 1
0, 0
R/W
FUNCTION
R/W
This bit is used to set the gain of the Rx PGA1.
00 = 0.25 V/V
01 = 0.5 V/V
10 = 1 V/V
11 = 2 V/V
R/W
This bit is used to set the gain of the Rx PGA2.
00 = 1 V/V
01 = 4 V/V
10 = 16 V/V
11 = 64 V/V
This bit is used to set the gain of the Tx PGA.
00 = 0.25 V/V
01 = 0.5 V/V
10 = 0.707 V/V
11 = 1 V/V
4, 5
1, 1
R/W
--
6
0
--
Reserved
--
7
0
--
Reserved
Table 11. Enable2 Register: Address 0x03
Default: 0x00
Enable2 Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
FUNCTION
ZC
0
0
R/W
This bit is used to enable/disable the ZC Block.
0 = disabled, 1 = enabled.
REF1
1
0
R/W
This bit is used to enable/disable the REF1 Block.
0 = disabled, 1 = enabled.
REF2
2
0
R/W
This bit is used to enable/disable the REF2 Block.
0 = disabled, 1 = enabled.
This bit is used to enable/disable the PA output stage.
When the PA output stage is enabled it functions normally with a
low output impedance, capable of driving heavy loads.
When the PA output stage is disabled it is placed into a high
impedance state.
0 = disabled, 1 = enabled.
PA_OUT
3
0
R/W
--
4
0
--
Reserved
--
5
0
--
Reserved
--
6
0
--
Reserved
--
7
0
--
Reserved
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Table 12. Control1 Register: Address 0x04
Default: 0x00
Control1 Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
FUNCTION
TX_CAL
0
0
R/W
This bit is used to enable/disable the TX calibration mode.
0 = disabled, 1 = enabled.
RX_CAL
1
0
R/W
This bit is used to enable/disable the RX calibration mode.
0 = disabled, 1 = enabled.
TX_PGA_CAL
2
0
R/W
This bit is used to enable/disable the TX PGA calibration mode.
0 = disabled, 1 = enabled.
CA_CBCD
3
0
R/W
This bit is used to select the frequency response of the Tx Filter
and Rx Filter.
0 = CENELEC A
1 = CENELEC B, C, D
--
4
0
--
Reserved
--
5
0
--
Reserved
TX_FLAG
6
0
R
This bit is used to indicate the status of the Tx Block.
0 = Tx Block is not ready for transmission.
1 = Tx Block is ready for transmission.
RX_FLAG
7
0
R
This bit is used to indicate the status of the Rx Block.
0 = Rx Block is not ready for reception.
1 = Rx Block is ready for reception.
Table 13. Control2 Register: Address 0x05
Default: 0x01
Control2 Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
--
0
0
--
Reserved
--
1
0
--
Reserved
--
2
0
--
Reserved
--
3
0
--
Reserved
--
4
0
--
Reserved
T_FLAG_EN
5
0
R/W
This bit is used to enable/disable the T_flag bit in the RESET
Register.
0 = disabled, 1 = enabled.
I_FLAG_EN
6
0
R/W
This bit is used to enable/disable the I_flag bit in the RESET
Register.
0 = disabled, 1 = enabled.
7
X
--
--
FUNCTION
Reserved
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Table 14. RESET Register: Address 0x09
Default: 0x00
Reset Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
--
0
0
--
Reserved
--
1
0
--
Reserved
2, 3, 4
0, 0, 0
W
These bits are used to perform a software reset of the ENABLE1,
ENABLE2, CONTROL2, CONTROL3, and GAIN SELECT
registers. Writing '101' to these registers performs a software reset.
R/W
This bit is used to indicate the status of a PA thermal overload.
0 = On read, indicates that no thermal overload has occurred since
the last reset.
0 = On write, resets this bit.
1 = On read, indicates that a thermal overload has occurred since
the last reset. Remains latched until reset.
This bit is used to indicate the status of a PA output current
overload.
0 = On read indicates that no current overload has occurred since
the last reset.
0 = On write, resets this bit.
1 = On read indicates that a current overload has occurred since
the last reset. Remains latched until reset.
SOFTRST0,
SOFTRST1,
SOFTRST2
T_FLAG
5
I_FLAG
--
0
6
0
R/W
7
0
--
FUNCTION
Reserved
Table 15. DieID Register: Address 0x0A
Default: 0x00
DieID Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
DIE ID<0>
0
0
R
The Die ID register is hard-wired.
DIE ID<1>
1
0
R
The Die ID register is hard-wired.
DIE ID<2>
2
0
R
The Die ID register is hard-wired.
DIE ID<3>
3
0
R
The Die ID register is hard-wired.
DIE ID<4>
4
0
R
The Die ID register is hard-wired.
DIE ID<5>
5
0
R
The Die ID register is hard-wired.
DIE ID<6>
6
0
R
The Die ID register is hard-wired.
DIE ID<7>
7
0
R
The Die ID register is hard-wired.
FUNCTION
Table 16. Revision Register: Address 0x0B
Default: 0x02
Revision Register <7:0>
BIT NAME
LOCATION
(0 = LSB)
DEFAULT
R/W
REVISION ID<0>
0
0
R
The revision register is hard-wired.
REVISION ID<1>
1
1
R
The revision register is hard-wired.
REVISION ID<2>
2
0
R
The revision register is hard-wired.
REVISION ID<3>
3
0
R
The revision register is hard-wired.
REVISION ID<4>
4
0
R
The revision register is hard-wired.
REVISION ID<5>
5
0
R
The revision register is hard-wired.
REVISION ID<6>
6
0
R
The revision register is hard-wired.
REVISION ID<7>
7
0
R
The revision register is hard-wired.
FUNCTION
38
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POWER SUPPLIES
The AFE031 has two low-voltage analog power-supply pins and one low-voltage digital supply pin. Internally, the
two analog supply pins are connected to each other through back-to-back electrostatic discharge (ESD)
protection diodes. These pins must be connected to each other on the application printed circuit board (PCB). It
is also recommended to connect the digital supply pin and the two analog supply pins together on the PCB. Both
low-voltage analog ground pins are also connected internally through back-to-back ESD protection diodes. These
ground pins should also be connected to the digital ground pin on the PCB. It is recommended to bypass the
low-voltage power supplies with a parallel combination of a 10-μf and 100-nf capacitor. The PA block is biased
separately from a high-voltage, high-current supply.
Two PA power supply pins and two PA ground pins are available to provide a path for the high currents
associated with driving the low impedance of the ac mains. Connecting the two PA supply pins together and
placing them close to the AFE031 is recommended. It is also recommended to place a bypass capacitor of 47 μF
to 100 μF in parellel with 100 nF as close as possible to the AFE031. Care must be taken when routing the high
current ground lines on the PCB to avoid creating voltage drops in the PCB ground that may vary with changes
in load current.
The AFE031 has many options to enable or disable the functional blocks to allow for flexible power-savings
modes. Table 17 shows the specific power supply that each functional block draws power from, as well as the
typical amount of power drawn from the associated power supplies for both the enabled and disabled states. For
additional information on power-supply requirements refer to Application Report SBOA130, Analog Front-End
Design for a Narrowband Power-Line Communications Modem Using the AFE031 (available for download at
www.ti.com).
Table 17. Power Consumption with Enable and Disable Times (Typical)
BLOCK
PA
Tx
Rx
ERx
ETx
DAC
ZC
REF1
REF2
DISABLE TIME
AVDD SUPPLY
CURRENT
DVDD SUPPLY
CURRENT
PA SUPPLY
CURRENT
10 μs
–
–
–
61 mA
–
10 μs
–
–
70 μA
10 μs
–
3.7 mA
–
–
Off
–
10 μs
1 μA
–
–
On
10 μs
–
5.3 mA
–
–
Off
–
10 μs
1 μA
–
–
On
10 μs
–
900 μA
–
–
Off
–
10 μs
1 μA
–
–
On
10 μs
–
1.2 mA
–
–
Off
–
10 μs
1 μA
–
–
On
10 μs
–
–
16 μA
–
Off
–
10 μs
–
1 μA
–
On
10 μs
–
25 μA
–
–
Off
–
10 μs
1 μA
–
–
On
10 μs
–
–
–
26 μA
Off
–
10 μs
–
–
8 μA
On
10 μs
–
25 μA
–
–
Off
–
10 μs
4 μA
–
–
STATUS
ENABLE TIME
On
Off
On
39
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PIN DESCRIPTIONS
DAC (Pin 7)
The DAC pin is used to configure the SPI to either read or write data to the Command and Data Registers, or to
write data to the DAC registers. Setting the DAC pin high allows access to the DAC registers. Setting the DAC
pin low allows access to the Command and Data Registers.
SD (Pin 8)
The Shutdown pin (SD) can be used to shut down the entire AFE031 for maximum power savings. When the SD
pin is low, normal operation of the AFE031 occurs. When the SD pin is high, all circuit blocks within the AFE031,
including the serial interface, are placed into the lowest-power operating modes. In this condition, the entire
AFE031 draws only 95 μA of current. All register contents at the time the AFE031 is placed into shutdown mode
are saved; upon re-enabling the AFE031, the register contents retain the respective saved values.
INT Pin (9)
The Interrupt pin (INT) can be used to signal the microprocessor of an unusual operating condition that results
from an anomaly on the ac mains. The INTpin can be triggered by two external circuit conditions, depending
upon the Enable Register settings. The AFE031 can be programmed to issue an interrupt on these conditions:
• Current Overload
• Thermal Overload
Current Overload
The maximum output current allowed from the Power Amplifier can be programmed with the external RSET
resistor connected between PA_ISET (pin 46) and ground. If a fault condition should occur and cause an
overcurrent event for the PA, the PA goes into current limit and the I_FLAG bit (location 6 in the RESET
Register) is set to a '1' if the I_Flag_EN bit (location 6 in the Control2 Register) is enabled. This configuration
results in an interrupt signal at the INT pin. The I_FLAG bit remains set to '1' even after the device returns to
normal operation. The I_FLAG bit remains at '1' until it is reset by the microprocessor.
If the I_FLAG_EN bit (location 6 in the Control2 Register) is disabled and a current overload condition occurs, the
PA goes into current-limit mode to protect the AFE031; however, the contents of the I_FLAG bit (location 6 in the
RESET Register) remain at the respective previous values (presumably '0' for normal operation), and the
AFE031 does not issue an interrupt at the INT pin.
Thermal Overload
The AFE031 contains internal protection circuitry that automatically disables the PA output stage if the junction
temperature exceeds +150°C. If a fault condition occurs that causes a thermal overload, and if the T_FLAG_EN
bit (location 5 in the Control2 Register) is enabled, the T_FLAG bit (location 5 in the RESET Register) is set to a
'1'. This configuration results in an interrupt signal at the INT pin. The AFE031 includes a thermal hysteresis and
allows the PA to resume normal operation when the junction temperature reduces to +135°C. The T_FLAG bit
remains set to a '1' even after the device returns to normal operation. The T_FLAG bit remains '1' until it is reset
by the microprocessor.
If the T_FLAG_EN bit (location 5 in the Control2 Register) is disabled and a thermal overload condition occurs,
the PA continues to go into thermal limit and protect the AFE031, but the contents of the T_FLAG bit (location 5
in the RESET Register) remain at the previous value (presumably '0' for normal operation), and the AFE031 does
not issue an interrupt at the INT pin.
Once an interrupt is signaled (that is, INT goes low), the contents of the I_FLAG and T_FLAG bits can be read
by the microprocessor to determine the type of interrupt that occurred. Using the Control2 Register, each
interrupt type (current or thermal) can be individually enabled or disabled, allowing full user customization of the
INT function. For proper operation of the interrupt pin it is recommended to configure the interrupt enable
registers in the Control2 Register by writing to bit locations 5, 6, and 7 following the information in Table 18 after
each time the AFE031 is powered on. Failure to properly configure bit locations 5, 6, and 7 after power on may
result in unexpected interrupt signals.
40
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Table 18 lists the register contents associated with each interrupt condition.
Table 18. Register Contents to Configure the Interrupt Pin
CONTROL2 REGISTER CONTENTS:
DETERMINE INTERRUPT PIN FUNCTIONALITY
I_FLAG_EN
(CURRENT
OVERLOAD)
T_FLAG_EN
(THERMAL
OVERLOAD)
FUNCTION
D7
D6
D5
POR (default values)
undefined
0
0
No interrupt
0
0
0
Interrupt on thermal overload only
0
0
1
Interrupt on current overload only
0
1
0
Interrupt on thermal or current
overload
0
1
1
TSENSE Pin (10)
The TSENSE pin is internally connected to the anode of a temperature-sensing diode located within the PA
output stage. Figure 45 shows a remote junction temperature sensor circuit that can be used to measure the
junction temperature of AFE031. Measuring the junction temperature of the AFE031 is optional and not required.
+3.3 V
0.1 mF
1
AFE031
V+
SCL
50 W
2
TSENSE
50 pF
3
D+
10 kW
(typ)
10 kW
(typ)
10 kW
(typ)
10 kW
(typ)
8
TMP411
SDA
7
DALERT/THERM2
THERM
SMBus
Controller
6
4
Over-Temperature
Fault
GND
5
Figure 45. Interfacing the TMP411 to the AFE031
Tx_FLAG (Pin 47)
The Tx_FLAG pin is an open drain output that indicates the readiness of the Tx signal path for transmission.
When the Tx_FLAG pin is high, the transmit signal path is enabled and ready for transmission. When the
Tx_FLAG pin is low, the transmit path is not ready for transmission.
Rx_FLAG (Pin 48)
The Rx_FLAG pin is an open drain output that indicates the readiness of the Rx signal path for transmission.
When the Rx_FLAG pin is high, the transmit signal path is enabled and ready for transmission. When the
Rx_FLAG pin is low, the transmit path is not ready for transmission.
41
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CALIBRATION MODES
The AFE031 can be configured for three different calibration modes: Tx Calibration, Rx Calibration, and Tx PGA
Calibration. Calibration values can be determined during the calibration process and stored in system memory. A
one-time calibration can be performed the first time that the system powers on; this calibration remains valid over
the full temperature range and operating life of the AFE031, independent of the number of power-on/power-off
cycles, as long as the calibration factors remain in the system memory. Calibration mode is accessed through the
Control1 Register. Note that calibration is not required.
Tx Calibration Mode
The Tx PGA + Tx Filter ac gain can be calibrated in Tx Calibration Mode. Figure 46 shows the signal path during
Tx Calibration mode.
C2000 MCU
AFE031
Line Coupling Interface
DAC
PGA
PA
LPF
SPI
SPI
PGA
PGA
LPF
Figure 46. Tx Calibration Mode Configuration
Rx Calibration Mode
The Tx PGA + Rx PGA1 + Rx Filter + Rx PGA2 ac gain can be calibrated in Rx Calibration mode. Figure 47
shows the signal path during Rx Calibration mode.
C2000 MCU
AFE031
DAC
Line Coupling Interface
PGA
PA
LPF
SPI
SPI
PGA
PGA
LPF
Figure 47. Rx Calibration Mode Configuration
42
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Tx PGA Calibration Mode
The Tx PGA ac gain can be calibrated in Tx PGA Calibration mode. Figure 48 shows the signal path during Tx
PGA Calibration mode.
C2000 MCU
AFE031
Line Coupling Interface
DAC
PGA
PA
LPF
SPI
SPI
PGA
PGA
LPF
Figure 48. Tx PGA Calibration Mode Configuration
BASIC CONFIGURATION
Figure 49 shows the AFE031 configured in a typical PLC analog front-end application. The schematic shows the
connections to the microprocessor and ac line. The values of the passive components in Figure 49 are suitable
for a single-phase powerline communications application in the CENELEC A band, connected to a 120-VAC or
240-VAC, 50-Hz or 60-Hz ac line.
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+15 V
C5
10 mF
C13
10 mF
3.3 V
R10
7.5 kW
R1
33 kW
C15
10 mF
C14
10 mF
C16
100 nF
L1
1 mH
R2
33 kW
D1
C6
10 mF
D2
+
N1
D3
GPIO
R12
4.7 W
C3
10 mF
Flexible PLC
Software Engine
R3
33 kW
38
3
5
SPI
Tx
Filter
Tx
PGA
12
23
22
C9
1 nF
C10
10 nF
Test
Point
23 kHz to
105 kHz
Fourth-Order
Passive
Passband
Filter
R13
150 W
25
C11
L4
10 nF 470 mH
C20
22 nF
R14
150 W
LPF
18
17
15
14
13
ADC IN
26
Rx
Filter
Rx
PGA2
C8
3.3 nF
C12
1 mF
28
L3
330 mH
27
LPF
C7
10 nF
C4
10 mF
Rx
PGA1
3.3 V
C2
24
11
3.3 V
LPF
Power
Amplifier
16
R5
10 kW
Rx
31
30
10
R4
10 kW
32
29
9
GPIO
Tx
8
21
GPIO
33
7
20
SPI
Two-Wire
Support
Circuitry
DAC
6
GPIO
C19
33 nF
34
DAC
Registers
19
SPI
Neutral
D4
TVS
35
4
SPI
Phase
+
N2
36
2
SPI
L2
15 mH
Line Coupling Circuit
Zero
Crossing
1
C18
470 nF
C17
10 nF
37
40
39
41
43
42
44
46
3.3 V
45
R6 through R9
10 kW each
48
3.3 V
47
GPIO
TMS320F28x
1.5:1
See Note (2)
C1
See Note (1)
R11
330 W
(1)
Recommended values for C1 and C2:
1.
2.
C1:
–
CENELEC A: 680 pF
–
CENELEC B, C, D: 270 pF
C2:
–
CENELEC A: 680 pF
–
CENELEC B, C, D: 560 pF
Figure 49. Typical Powerline Communications Modem Application
44
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LINE-COUPLING CIRCUIT
The line-coupling circuit is one of the most critical circuits in a powerline modem. The line-coupling circuit has
two primary functions: first, to block the low-frequency signal of the mains (commonly 50 Hz or 60 Hz) from
damaging the low-voltage modem circuitry; second, to couple the modem signal to and from the ac mains. A
typical line-coupling circuit is shown in Figure 50.
Power
Amplifier
Low-Voltage
Capacitor
High-Voltage
Capacitor
+
N1
L
Phase
+
N2
Neutral
Figure 50. Simplified Line Coupling Circuit
For additional information on line-coupling interfaces with the AFE031, refer to Application Report SBOA130,
Analog Front-End Design for a Narrowband Power-Line Communications Modem Using the AFE031 (available
for download at www.ti.com).
CIRCUIT PROTECTION
Powerline communications are often located in operating environments that are harsh for electrical components
connected to the ac line. Noise or surges from electrical anomalies such as lightning, capacitor bank switching,
inductive switching, or other grid fault conditions can damage high-performance integrated circuits if they are not
properly protected. The AFE031 can survive even the harshest conditions if several recommendations are
followed.
First, dissipate as much of the electrical disturbance before it reaches the AFE031 with a multi-layer approach
using metal-oxide varistors (MOVs), transient voltage suppression diodes (TVSs), Schottky diodes, and a Zener
diode. Figure 51 shows the recommended strategy for transient overvoltage protection.
PA
Power Supply
AFE031
D1
D2
Low-Voltage
Capacitor
High-Voltage
Capacitor
Phase
+
N1
+
N2
MOV
D3
Power
Amplifier
Neutral
TVS
Figure 51. Transient Overvoltage Protection for AFE031
Note that the high-voltage coupling capacitor must be able to withstand pulses up to the clamping protection
provided by the MOV. A metalized polypropylene capacitor, such as the 474MKP275KA from Illinois Capacitor,
Inc., is rated for 50 Hz to 60 Hz, 250 VAC to 310 VAC, and can withstand 24 impulses of 2.5 kV.
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Table 19 lists several recommended transient protection components.
Table 19. Recommended Transient Protection Devices
120 VAC, 60 Hz
COMPONENT
DESCRIPTION
MANUFACTURER
MFR PART NO (OR EQUIVALENT)
D1
Zener diode
Diodes, Inc.
1SMB59xxB (1)
D2, D3
Schottky diode
Diodes, Inc.
1N5819HW
TVS
Transient voltage suppressor
Diodec Semiconductor
P6SMBJxxC (2)
MOV
Varistor
LittleFuse
TMOV20RP140E
HV Cap
High-voltage capacitor
Illinois Capacitor, Inc
474MKP275KA (3)
COMPONENT
DESCRIPTION
MANUFACTURER
MFR PART NO (OR EQUIVALENT)
D1
Zener diode
Diodes, Inc.
1SMB59xxB (1)
240 VAC, 50 Hz
(1)
(2)
(3)
D2, D3
Schottky diode
Diodes, Inc.
1N5819HW
TVS
Transient voltage suppressor
Diodec Semiconductor
P6SMBJxxC (2)
MOV
Varistor
LittleFuse
TMOV20RP300E
HV Cap
High-voltage capacitor
Illinois Capacitor, Inc
474MKP275KA (3)
Select the Zener breakdown voltage at the lowest available rating beyond the normal power-supply operating range.
Select the TVS breakdown voltage at or slightly greater than (0.5 ● PA_VS).
A common value for the high-voltage capacitor is 470 nF. Other values may be substituted depending on the requirements of the
application. Note that when making a substitution, it is important in terms of reliability that the capacitor be selected from the same
familiy or equivalent family of capacitors rated to withstand high-voltage surges.
THERMAL CONSIDERATIONS
In a typical powerline communications application, the AFE031 dissipates 2 W of power when transmitting into
the low impedance of the ac line. This amount of power dissipation can increase the junction temperature, which
in turn can lead to a thermal overload that results in signal transmission interruptions if the proper thermal design
of the PCB has not been performed. Proper management of heat flow from the AFE031 as well as good PCB
design and construction are required to ensure proper device temperature, maximize performance, and extend
device operating life.
The AFE031 is assembled into a 7-mm2 x 7-mm2, 48-lead, QFN package. As Figure 52 shows, this QFN
package has a large area exposed thermal pad on the underside that is used to conduct heat away from the
AFE031 and into the underlying PCB.
Figure 52. QFN Package with Large Area Exposed Thermal Pad
Some heat is conducted from the silicon die surface through the plastic packaging material and is transferred into
the ambient environment. Because plastic is a relatively poor conductor of heat, however, this route is not the
primary thermal path for heat flow. Heat also flows across the silicon die surface to the bond pads, through the
wire bonds, into the package leads, and finally into the top layer of the PCB. While both of these paths for heat
flow are important, the majority (nearly 80%) of the heat flows downward, through the silicon die, into the
thermally-conductive die attach epoxy, and into the exposed thermal pad on the underside of the package (see
Figure 53). Minimizing the thermal resistance of this downward path to the ambient environment maximizes the
life and performance of the device.
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Less than 1%
~20%
~20%
~80%
Figure 53. Heat Flow in the QFN Package
The exposed thermal pad must be soldered to the PCB thermal pad. The thermal pad on the PCB should be the
same size as the exposed thermal pad on the underside of the QFN package. Refer to Application Report,
QFN/SON PCB Attachment, literature number SLUA271A, for recommendations on attaching the thermal pad to
the PCB. Figure 54 illustrates the direction of heat spreading into the PCB from the device.
AFE031
Figure 54. Heat Spreading into PCB
The heat spreading into the PCB is maximized if the thermal path is uninterrupted. Best results are achieved if
the heat-spreading surfaces are filled with copper to the greatest extent possible, maximizing the percent area
covered on each layer. As an example, a thermally robust, multilayer PCB design may consist of four layers with
copper (Cu) coverage of 60% in the top layer, 85% and 90% in the inner layers, respectively, and 95% on the
bottom layer.
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Increasing the number of layers in the PCB, using thicker copper, and increasing the PCB area are all factors
that improve the spread of heat. Figure 55 through Figure 57, respectively, show thermal resistance performance
as a function of each of these factors.
THERMAL RESISTANCE vs NUMBER OF PCB LAYERS
36
2
PCB Area = 3 in , 2 oz Cu
(Results are from thermal
simulations)
Thermal Resistance (°C/W)
34
32
30
28
26
24
22
20
1
2
4
3
5
6
7
8
Number of Layers
Figure 55. Thermal Resistance as a Function of the Number of Layers in the PCB
THERMAL RESISTANCE vs BOARD AREA
28
Four-Layer PCB, 2 oz Cu
(Results are from thermal
simulations)
Thermal Resistance (°C/W)
26
24
22
20
Measured
Data
18
16
14
12
10
2
4
6
8
10
12
14
2
PCB Area (in )
Figure 56. Thermal Resistance as a Function of PCB Area
35
Four-Layer PCB, PCB
2
Area = 4.32 in , 2 oz Cu
(Results are from thermal
simulations)
Thermal Resistance (°C/W)
33
31
29
27
25
23
21
19
17
15
0.5
1
1.5
2
2.5
Cu Thickness (oz)
Figure 57. Thermal Resistance as a Function of Copper Thickness
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For additional information on thermal PCB design using exposed thermal pad packages, refer to Application
Report SBOA130, Analog Front-End Design for a Narrowband Power-Line Communications Modem Using the
AFE031 and Application Report SLMA002E, PowerPAD™ Thermally-Enhanced Package (both available for
download at www.ti.com).
Powerline Communications Developer’s Kit
A PLC developer’s kit (TMDSPLCKIT-V3) is available to order at www.ti.com/plc. This kit offers complete
hardware and software solutions for introducing flexible, efficient, and reliable networking capabilities to a wide
variety of applications. With unique modular hardware architecture and flexible software framework, TI’s PLC
solutions are the only PLC-based technology capable of supporting multiple protocol standards and modulation
schemes with a single platform. This technology enables designers to leverage product lines across global
markets. The flexibility of the platform also allows developers to optimize hardware and software performance for
specific environmental operating conditions while simplifying end-to-end product design. Based on TI’s powerful
C2000™ microcontroller architecture and the AFE031, developers can select the correct blend of processing
capacity and peripherals to either add powerline communications to an existing design or implement a complete
application with PLC communications.
The C2000 Powerline Modem Developer's Kit enables easy development of software-based PLC modems. The
kit includes two PLC modems based on the C2000 TMS320F28069 controlCARD and the AFE031. The included
PLC SUITE software supports several communication techniques, including OFDM (PRIME/G3 and FlexOFDM)
and SFSK. The kit also includes onboard USB JTAG emulation and Code Composer Studio.
PACKAGING/MECHANICALS
Complete mechanical drawings and packaging information are appended to the end of this data sheet.
49
Copyright © 2010–2011, Texas Instruments Incorporated
Product Folder Link(s): AFE031
PACKAGE OPTION ADDENDUM
www.ti.com
5-Oct-2011
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
AFE031AIRGZR
ACTIVE
VQFN
RGZ
48
2500
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
AFE031AIRGZT
ACTIVE
VQFN
RGZ
48
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
Samples
(Requires Login)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Oct-2011
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
AFE031AIRGZR
VQFN
RGZ
48
2500
330.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
AFE031AIRGZT
VQFN
RGZ
48
250
180.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Oct-2011
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
AFE031AIRGZR
VQFN
RGZ
48
2500
346.0
346.0
33.0
AFE031AIRGZT
VQFN
RGZ
48
250
210.0
185.0
35.0
Pack Materials-Page 2
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