Microchip MIC45212-1 26v, 14a dc-to-dc power module Datasheet

MIC45212-1/-2
26V, 14A DC-to-DC Power Module
Features
General Description
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The MIC45212 is a synchronous, step-down regulator
module, featuring a unique adaptive ON-time control
architecture. The module incorporates a DC-to-DC
controller, power MOSFETs, bootstrap diode, bootstrap
capacitor and an inductor in a single package, simplifying
the design and layout process for the end user.
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•
•
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No Compensation Required
Up to 14A Output Current
>93% Peak Efficiency
Output Voltage: 0.8V to 0.85*VIN with
±1% Accuracy
Adjustable Switching Frequency from 200 kHz to
600 kHz
Enable Input and Open-Drain Power Good Output
Hyper Speed Control® (MIC45212-2) Architecture
enables Fast Transient Response
HyperLight Load® (MIC45212-1) improves Light
Load Efficiency
Supports Safe Start-up into Pre-Biased Output
-40°C to +125°C Junction Temperature Range
Thermal Shutdown Protection
Short-Circuit Protection with Hiccup mode
Adjustable Current Limit
Available in 64-Pin 12 mm x 12 mm x 4 mm QFN
Package
This highly integrated solution expedites system
design and improves product time-to-market. The
internal MOSFETs and inductor are optimized to
achieve high efficiency at a low output voltage. The fully
optimized design can deliver up to 14A current under a
wide input voltage range of 4.5V to 26V, without
requiring additional cooling.
The MIC45212-1 uses the HyperLight Load (HLL) while
the MIC45212-2 uses the Hyper Speed Control (HSC)
architecture, which enables ultra-fast load transient
response, allowing for a reduction of output capacitance. The MIC45212 offers 1% output accuracy that
can be adjusted from 0.8V to 0.85*VIN with two external
resistors. Additional features include thermal shutdown
protection, input undervoltage lockout, adjustable
current limit and short-circuit protection. The MIC45212
allows for safe start-up into a pre-biased output.
Applications
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•
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High-Power Density Point-of-Load Conversion
Servers, Routers, Networking and Base Stations
FPGAs, DSP and Low-Voltage ASIC Power Supplies
Industrial and Medical Equipment
Data sheet and other support documentation can be
found on the Microchip web site at: www.microchip.com.
Typical Application Schematic
VIN
12V
PVDD
ANODE
5VDD
BST
PG
RIA
VOUT
PVIN
MIC45212
VIN
CIN
VOUT
0.8V to 0.85 * VIN/Up to 14A
FREQ
FB
RIB
CFF
ON
COUT
RFB2
SW
OFF
RFB1
RLIM
EN
GND
 2017 Microchip Technology Inc.
ILIM
PGND
DS20005607A-page 1
MIC45212-1/-2
Package Types
54
53
ANODE
55
BST
56
BST
57
NC
58
BST
GND
59
PG
60
FB
FREQ
61
VIN
62
EN
63
5VDD
GND
64
5VDD
MIC45212-1/-2
64-Pin 12 mm x 12 mm x 4 mm QFN (Top
View)
52 51
GND
1
PVDD
2
PVDD
3
ILIM
4
PGND
5
46
RIA
KEEPOUT
BST
PGND
ANODE
49
ANODE
48
RIB
47
RIA
6
45
SW
7
44
SW
SW
8
43
SW
SW
9
42
SW
SW
10
41
SW
KEEPOUT
11
40
SW
PVIN
12
39
SW
PVIN
13
PVIN
14
PGND
SW
PVIN ePAD
38
SW
37
KEEPOUT
36
VOUT
PVIN
15
PVIN
16
35
VOUT
PVIN
17
34
VOUT
PVIN
18
33
VOUT
VOUT ePAD
31
32
VOUT
30
VOUT
29
VOUT
28
VOUT
27
VOUT
26
VOUT
25
VOUT
24
VOUT
23
VOUT
PVIN
22
KEEPOUT
21
PVIN
20
PVIN
19
PVIN
DS20005607A-page 2
50
 2017 Microchip Technology Inc.
MIC45212-1/-2
Functional Block Diagram
VIN
5VDD
VDD
VIN
PVIN
PVDD
PVDD
VOUT
ILIM
ILIM
 2017 Microchip Technology Inc.
DS20005607A-page 3
MIC45212-1/-2
1.0
ELECTRICAL CHARACTERISTICS
Absolute Maximum Ratings†
VPVIN, VVIN to PGND................................................................................................................................. –0.3V to +30V
VPVDD, V5VDD, VANODE to PGND ................................................................................................................ –0.3V to +6V
VSW, VFREQ, VILIM, VEN to PGND .................................................................................................. –0.3V to (VIN + 0.3V)
VBST to VSW................................................................................................................................................. –0.3V to +6V
VBST to PGND .......................................................................................................................................... –0.3V to +36V
VPG to PGND .............................................................................................................................. –0.3V to (5VDD + 0.3V)
VFB, VRIB to PGND...................................................................................................................... –0.3V to (5VDD + 0.3V)
PGND to GND ........................................................................................................................................... -0.3V to +0.3V
Junction Temperature........................................................................................................................................... +150°C
Storage Temperature (TS) ..................................................................................................................... –65°C to +150°C
Lead Temperature (soldering, 10s) ...................................................................................................................... +260°C
†
Notice: Stresses above those listed under “Maximum Ratings” may cause permanent damage to the device. This
is a stress rating only and functional operation of the device at those or any other conditions above those indicated in the operational sections of this specification is not intended. Exposure to maximum rating conditions for
extended periods may affect device reliability.
Operating Ratings(1)
Supply Voltage (VPVIN, VVIN) ......................................................................................................................... 4.5V to 26V
Output Current ........................................................................................................................................................... 14A
Enable Input (VEN) ............................................................................................................................................ 0V to VIN
Power-Good (VPG) ......................................................................................................................................... 0V to 5VDD
Junction Temperature (TJ)..................................................................................................................... –40°C to +125°C
Junction Thermal Resistance(2)
12 mm x 12 mm x 4 mm QFN-64 (JA) ...........................................................................................................12.6°C/W
12 mm x 12 mm 4 mm QFN-64 (JC) ................................................................................................................3.5°C/W
Note 1: The device is not ensured to function outside the operating range.
2: JA and JC were measured using the MIC45212 evaluation board.
DS20005607A-page 4
 2017 Microchip Technology Inc.
MIC45212-1/-2
ELECTRICAL CHARACTERISTICS(1)
TABLE 1-1:
Electrical Specifications: unless otherwise specified, VPVIN = VVIN; VIN = VEN = 12V; VOUT = 3.3V;
VBST – VSW = 5V; TJ = +25°C. Boldface values indicate –40°C  TJ  +125°C.
Symbol
Parameter
Min.
Typ.
Max.
Units
Test Conditions
Power Supply Input
VIN, VPVIN
Input Voltage Range
4.5
—
26
V
IQ
Quiescent Supply Current
(MIC45212-1)
—
—
0.75
mA
VFB = 1.5V
IQ
Quiescent Supply Current
(MIC45212-2)
—
2.1
3
mA
VFB = 1.5V
—
0.37
—
mA
PVIN = VIN = 12V,
VOUT = 1.8V, IOUT = 0A,
fSW = 600 kHz
—
IIN
Operating Current:
MIC45208-1
—
54
—
ISHDN
Shutdown Supply Current
—
0.1
10
µA
SW = Unconnected, VEN = 0V
VDD
5VDD Output Voltage
4.8
5.1
5.4
V
VIN = 7V to 26V, I5VDD = 10
mA
UVLO
MIC45208-2
5VDD Output
5VDD UVLO Threshold
3.8
4.2
4.6
V
V5VDD Rising
UVLO_HYS 5VDD UVLO Hysteresis
—
400
—
mV
V5VDD Falling
VDD(LR)
0.6
2
3.6
%
0.792
0.8
0.808
0.784
0.8
0.816
—
5
500
nA
LDO Load Regulation
I5VDD = 0 to 40 mA
Reference
VFB
Feedback Reference Voltage
IFB_BIAS
Feedback Bias Current
V
TJ = +25°C
–40°C  TJ  +125°C
VFB = 0.8V
Enable Control
ENHIGH
EN Logic Level High
1.8
—
—
V
—
ENLOW
EN Logic level Low
—
—
0.6
V
—
ENHYS
EN Hysteresis
—
200
—
mV
—
IENBIAS
EN Bias Current
—
5
10
µA
VEN = 12V
400
600
750
—
350
—
Oscillator
VFREQ = VIN, IOUT = 2A
fSW
Switching Frequency
DMAX
Maximum Duty Cycle
—
85
—
%
—
DMIN
Minimum Duty Cycle
—
0
—
%
VFB = 1V
tOFF(MIN)
Minimum OFF-Time
140
200
260
ns
—
—
3
—
ms
FB Rising from 0V to 0.8V
VCL_OFFSET Current-Limit Threshold
–30
–14
0
mV
VFB = 0.79V
VSC
Short-Circuit Threshold
–23
–7
9
mV
VFB = 0V
ICL
Current-Limit Source Current
50
70
90
µA
VFB = 0.79V
ISC
Short-Circuit Source Current
25
35
45
µA
VFB = 0V
ISW_Leakage
SW, BST Leakage Current
—
—
10
µA
—
IFREQ_LEAK
FREQ Leakage Current
—
—
10
µA
—
kHz
VFREQ = 50% VIN, IOUT = 2A
Soft Start
tSS
Soft Start Time
Short-Circuit Protection
Leakage
Note 1:
Specification for packaged product only.
 2017 Microchip Technology Inc.
DS20005607A-page 5
MIC45212-1/-2
TABLE 1-1:
ELECTRICAL CHARACTERISTICS(1) (CONTINUED)
Electrical Specifications: unless otherwise specified, VPVIN = VVIN; VIN = VEN = 12V; VOUT = 3.3V;
VBST – VSW = 5V; TJ = +25°C. Boldface values indicate –40°C  TJ  +125°C.
Symbol
Parameter
Min.
Typ.
Max.
Units
Test Conditions
Power Good (PG)
VPG_TH
PG Threshold Voltage
85
90
95
%VOUT Sweep VFB from Low-to-High
%VOUT Sweep VFB from High-to-Low
VPG_HYS
PG Hysteresis
—
6
—
tPG_DLY
PG Delay Time
—
100
—
µs
Sweep VFB from Low-to-High
VPG_LOW
PG Low Voltage
—
70
200
mV
VFB < 90% x VNOM,
IPG = 1 mA
Thermal Protection
TSHD
Overtemperature Shutdown
—
160
—
°C
TJ Rising
TSHD_HYS
Overtemperature Shutdown
Hysteresis
—
15
—
°C
—
Note 1:
Specification for packaged product only.
DS20005607A-page 6
 2017 Microchip Technology Inc.
MIC45212-1/-2
2.0
Note:
TYPICAL PERFORMANCE CURVES
The graphs and tables provided following this note are a statistical summary based on a limited number of
samples and are provided for informational purposes only. The performance characteristics listed herein
are not tested or guaranteed. In some graphs or tables, the data presented may be outside the specified
operating range (e.g., outside specified power supply range) and therefore outside the warranted range.
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
FIGURE 2-1:
VIN Operating Supply
Current vs. Input Voltage (MIC45212-1).
FIGURE 2-4:
Temperature.
VDD Supply Voltage vs.
FIGURE 2-2:
VIN Operating Supply
Current vs. Temperature (MIC45212-2).
FIGURE 2-5:
Temperature.
Enable Threshold vs.
FIGURE 2-3:
Input Voltage.
FIGURE 2-6:
Temperature.
EN Bias Current vs.
VIN Shutdown Current vs.
 2017 Microchip Technology Inc.
DS20005607A-page 7
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
FIGURE 2-7:
Temperature.
Feedback Voltage vs.
FIGURE 2-10:
vs. Temperature.
FIGURE 2-8:
vs.Temperature.
Output Voltage
FIGURE 2-11:
Efficiency vs. Output
Current (MIC45212-1, VIN = 5V).
FIGURE 2-9:
vs.Temperature.
Switching Frequency
FIGURE 2-12:
Efficiency vs. Output
Current (MIC45212-1, VIN = 12V).
DS20005607A-page 8
Output Peak Current-Limit
 2017 Microchip Technology Inc.
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
FIGURE 2-13:
Efficiency vs. Output
Current (MIC45212-1, VIN = 24V).
FIGURE 2-16:
Efficiency vs. Output
Current (MIC45212-2, VIN = 24V).
FIGURE 2-14:
Efficiency vs. Output
Current (MIC45212-2, VIN = 5V).
FIGURE 2-17:
IC Power Dissipation vs.
Output Current (MIC45212-2, VIN = 5V).
FIGURE 2-15:
Efficiency vs. Output
Current (MIC45212-2, VIN = 12V).
FIGURE 2-18:
IC Power Dissipation vs.
Output Current (MIC45212-2, VIN = 12V).
 2017 Microchip Technology Inc.
DS20005607A-page 9
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
FIGURE 2-19:
IC Power Dissipation
vs. Output Current (MIC45212-2, VIN = 24V).
FIGURE 2-20:
DS20005607A-page 10
FIGURE 2-21:
(MIC45212-1).
Load Regulation
Line Regulation.
 2017 Microchip Technology Inc.
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
y
VIN Soft Turn On
VIN
(10V/div)
VIN = 12V
VOUT = 1.8V
IOUT = 14A
VOUT
(1V/div)
VEN
(2V/div)
PGOOD
(5V/div)
VOUT
(1V/div)
IIN
(5A/div)
IIN
(2A/div)
Time (2ms/div)
Time (2ms/div)
FIGURE 2-22:
VIN Soft Turn-On.
FIGURE 2-25:
VOUT
(1V/div)
VIN = 12V
VOUT = 1.8V
IOUT = 1A
VPRE-BIAS = 0.5V
VOUT
(1V/div)
PGOOD
(5V/div)
VIN = 12V
VOUT = 1.8V
IOUT = 14A
IIN
(5A/div)
PGOOD
(5V/div)
Time (8ms/div)
Time (2ms/div)
VIN Soft Turn-Off.
FIGURE 2-26:
Output.
y
VIN = 12V
VOUT = 1.8V
IOUT = 14A
VEN
(2V/div)
VOUT
(1V/div)
IIN
(2A/div)
IIN
(2A/div)
Time (2ms/div)
Enable Turn-On Delay and
 2017 Microchip Technology Inc.
VIN Start-up with Pre-Biased
ab e u
VOUT
(1V/div)
FIGURE 2-24:
Rise Time.
p
VIN
(10V/div)
VIN
(10V/div)
VEN
(2V/div)
Enable Turn-Off Delay.
p
VIN Soft Turn Off
FIGURE 2-23:
VIN = 12V
VOUT = 1.8V
IOUT = 14A
O / u
O
VIN = 12V
VOUT = 1.8V
IOUT = 14A
Time (8ms/div)
FIGURE 2-27:
Enable Turn-On/Turn-Off.
DS20005607A-page 11
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
Output Recovery from Short Circuit
Power-Up Into Short Circuit
VIN
(10V/div)
VOUT
(20mV/div)
VOUT
(1V/div)
VIN = 12V
VOUT = 1.8V
VIN = 12V
VOUT = 1.8V
IOUT = Short = Wire Across Output
IIN
(1A/div)
IOUT
(5A/div)
Time (2ms/div)
FIGURE 2-28:
Time (8ms/div)
Power-up into Short Circuit.
FIGURE 2-31:
Circuit.
VIN = 12V
VOUT = 1.8V
IOUT = Short = Wire Across Output
VOUT
(50mV/div)
VOUT
(1V/div)
VIN = 12V
VOUT = 1.8V
IPK-CL = 20.2A
IOUT
(10A/div)
IIN
(200mA/div)
Time (800μs/div)
FIGURE 2-29:
Output Recovery from Short
Peak Current Limit Threshold
Enabled Into Short Circuit
VEN
(2V/div)
Pulse: 2Hz; 0V - 3.3V; 20ms
Enabled into Short Circuit.
Time (8ms/div)
FIGURE 2-32:
Threshold.
Peak Current-Limit
Short Circuit
VIN = 12V
VOUT = 1.8V
VOUT
(1V/div)
Pulse: 2Hz; 0V - 3.3V; 20ms
IOUT
(5A/div)
Time (2ms/div)
FIGURE 2-30:
Short Circuit During Steady
State with 14A Load.
DS20005607A-page 12
FIGURE 2-33:
Output Recovery from
Thermal Shutdown.
 2017 Microchip Technology Inc.
MIC45212-1/-2
Note: Unless otherwise indicated, VIN = VEN = 12V, VOUT = 1.8V, VBST – VSW = 5V, TJ = +25°C.
g
a se t
VIN = 12V
VOUT = 1.8V
IOUT = 14A
VOUT
(20mV/div)
espo se (
VOUT
(100mV/div)
C 5
)
VIN = 12V
VOUT = 1.8V
IOUT = 1A to 8A
VSW
(5V/div)
IOUT
(5A/div)
IOUT
(10A/div)
Time (40μs/div)
Time (1μs/div)
FIGURE 2-34:
di/dt = 2A/μs
COUT = 2 x 100μF + 270μF POS
Switching Waveforms.
FIGURE 2-37:
(MIC45212-1).
Transient Response
p
Switching Waveforms (MIC45212 1)
(
VOUT
(100mV/div)
VOUT
(20mV/div)
AC-Coupled
)
VIN = 12V
VOUT = 1.8V
IOUT = 7A to 14A
VIN = 12V
VOUT = 1.8V
IOUT = 50mA
VSW
(10V/div)
IOUT
(50mA/div)
IOUT
(5A/div)
Time (40μs/div)
Time (20μs/div)
FIGURE 2-35:
(MIC45212-1).
Switching Waveforms
g
(
,
FIGURE 2-38:
(MIC45212-2).
)
Transient Response
OUT
VIN = 12V
VOUT = 1.8V
IOUT = 0A
VOUT
(20mV/div)
di/dt = 2A/μs
COUT = 2 x 100μF + 270μF POS
VEN
(2V/div)
μ
VIN = 12V
VOUT = 1.8V
IOUT = 14A
VOUT
(1V/div)
VSW
(5V/div)
IOUT
(10A/div)
IIN
(2A/div)
Time (1μs/div)
FIGURE 2-36:
Switching Waveforms
(IOUT = 0A, MIC45212-2)
 2017 Microchip Technology Inc.
Output ALE cap, 3000μF
Time (8ms/div)
FIGURE 2-39:
Inrush with COUT = 3000 µF.
DS20005607A-page 13
MIC45212-1/-2
3.0
PIN DESCRIPTIONS
The descriptions of the pins are listed in Table 3-1.
TABLE 3-1:
PIN FUNCTION TABLE
MIC45212
Pin Number
Pin Name
1, 56, 64
GND
Analog Ground: Connect bottom feedback resistor to GND. GND and PGND are
internally connected.
2, 3
PVDD
PVDD: Supply input for the internal low-side power MOSFET driver.
4
ILIM
5, 6
PGND
Power Ground: PGND is the return path for the step-down power module power stage.
The PGND pin connects to the sources of the internal low-side power MOSFET, the
negative terminals of input capacitors and the negative terminals of output capacitors.
7-10, 38-44
SW
The SW pin connects directly to the switch node. Due to the high-speed switching on this
pin, the SW pin should be routed away from sensitive nodes. The SW pin also senses the
current by monitoring the voltage across the low-side MOSFET during off time.
12-22
PVIN
Power Input Voltage: Connection to the drain of the internal high-side power MOSFET.
Connects an input capacitor from PVIN to PGND.
24-36
VOUT
Power Output Voltage: Connected to the internal inductor. The output capacitor should
be connected from this pin to PGND, as close to the module as possible.
46, 47
RIA
Pin Function
Current Limit: Connect a resistor between ILIM and SW to program the current limit.
Ripple Injection Pin A: Leave floating, no connection.
48
RIB
49-51
ANODE
Ripple Injection Pin B: Connect this pin to FB.
52-54
BST
Connection to the internal bootstrap circuitry and high-side power MOSFET drive
circuitry. Leave floating, no connection.
55
NC
No Connection.
57
FB
Feedback: Input to the transconductance amplifier of the control loop. The FB pin is
referenced to 0.8V. A resistor divider connecting the feedback to the output is used to
set the desired output voltage. Connect the bottom resistor from FB to GND.
58
PG
Power Good: Open-Drain Output. If used, connect to an external pull-up resistor of at
least 10 kOhm between PG and the external bias voltage.
59
EN
Enable: A logic signal to enable or disable the step-down regulator module operation.
The EN pin is TTL/CMOS compatible. Logic high = enable, logic low = disable or
shutdown. Do not leave floating.
60
VIN
Internal 5V Linear Regulator Input: A 1 µF ceramic capacitor from VIN to GND is
required for decoupling.
61
FREQ
Switching Frequency Adjust: Use a resistor divider from VIN to GND to program the
switching frequency. Connecting FREQ to VIN sets frequency = 600 kHz.
62, 63
5VDD
Internal +5V linear regulator output. Powered by VIN, 5VDD is the internal supply bus for
the device. In the applications with VIN<+5.5V, 5VDD should be tied to VIN to bypass
the linear regulator.
Anode Bootstrap Diode: Anode connection of internal bootstrap diode; this pin should be
connected to the PVDD pin.
11, 23, 37, 45
KEEPOUT
—
PVIN ePAD
PVIN Exposed Pad: Internally connected to the PVIN pins.
—
VOUT ePAD
VOUT Exposed Pad: Internally connected to the VOUT pins.
DS20005607A-page 14
Depopulated pin positions.
 2017 Microchip Technology Inc.
MIC45212-1/-2
4.0
FUNCTIONAL DESCRIPTION
The MIC45212 is an adaptive on-time synchronous
buck regulator module, built for high input voltage to
low output voltage conversion applications. The
MIC45212 is designed to operate over a wide input
voltage range, from 4.5V to 26V, and the output is
adjustable with an external resistor divider. An adaptive
ON-time control scheme is employed to obtain a
constant switching frequency in steady state and to
simplify the control compensation. Hiccup mode overcurrent protection is implemented by sensing low-side
MOSFET’s RDS(ON). The device features internal soft
start, enable, UVLO and thermal shutdown. The module
has integrated switching FETs, inductor, bootstrap
diode, resistor, capacitor and controller.
4.1
As shown in Figure 4-1, in association with
Equation 4-1, the output voltage is sensed by the
MIC45212 Feedback pin, FB, via the voltage dividers,
RFB1 and RFB2, and compared to a 0.8V reference voltage, VREF, at the error comparator through a low-gain
transconductance (gM) amplifier. If the feedback voltage
decreases and falls below 0.8V, then the error comparator will trigger the control logic and generate an ON-time
period. The ON-time period length is predetermined by
the “Fixed tON Estimator” circuitry.
RFB1
Compensation
Comp
gM
–
+
–
+
FB
RFB2
VREF +
0.8V –
FIGURE 4-1:
FB Pin.
Output Voltage Sense via
EQUATION 4-1:
ON-TIME ESTIMATION
tON(ESTIMATED) =
VOUT
VIN  fSW
Where:
VOUT = Output voltage
The maximum duty cycle is obtained from the 200 ns
tOFF(MIN):
EQUATION 4-2:
Theory of Operation
EA
At the end of the ON-time period, the internal high-side
driver turns off the high-side MOSFET and the low-side
driver turns on the low-side MOSFET. In most cases,
the OFF-time period length depends upon the feedback voltage. When the feedback voltage decreases
and the output of the gM amplifier falls below 0.8V, the
ON-time period is triggered and the OFF-time period
ends. If the OFF-time period determined by the feedback voltage, is less than the minimum OFF-time
tOFF(MIN), which is about 200ns, the MIC45212 control
logic will apply the tOFF(MIN) instead. tOFF(MIN) is
required to maintain enough energy in the Boost
Capacitor (CBST) to drive the high-side MOSFET.
DMAX =
MAXIMUM DUTY CYCLE
200 ns
tS – tOFF(MIN)
=1– t
tS
S
Where:
tS = 1/fSW
It is not recommended to use the MIC45212 device
with an OFF-time close to tOFF(MIN) during steady-state
operation.
The adaptive ON-time control scheme results in a
constant switching frequency in the MIC45212 during
steady-state operation. Also, the minimum tON results
in a lower switching frequency in high VIN to VOUT
applications. During load transients, the switching
frequency is changed due to the varying OFF-time.
To illustrate the control loop operation, we will analyze
both the steady-state and load transient scenarios. For
easy analysis, the gain of the gM amplifier is assumed
to be 1. With this assumption, the inverting input of the
error comparator is the same as the feedback voltage.
Figure 4-2 shows the MIC45212 control loop timing
during steady-state operation. During steady-state
operation, the gM amplifier senses the feedback voltage ripple, which is proportional to the output voltage
ripple, plus injected voltage ripple, to trigger the
ON-time period. The ON-time is predetermined by the
tON estimator. The termination of the OFF-time is
controlled by the feedback voltage. At the valley of the
feedback voltage ripple, which occurs when VFB falls
below VREF, the OFF-time period ends and the next
ON-time period is triggered through the control logic
circuitry.
VIN = Power stage input voltage
fSW = Switching frequency
 2017 Microchip Technology Inc.
DS20005607A-page 15
MIC45212-1/-2
Unlike true Current mode control, the MIC45212 uses
the output voltage ripple to trigger an ON-time period.
The output voltage ripple is proportional to the inductor
current ripple if the ESR of the output capacitor is large
enough.
IL
IL(PP)
IOUT
VOUT
VOUT(PP) = ESRCOUT IL(PP)
VFB
VFB(PP) = VOUT(PP) 
VREF
DH
RFB2
RFB1 + RFB2
Trigger ON-Time if VFB is Below VREF
Estimated ON-time
FIGURE 4-2:
Timing.
MIC45212 Control Loop
Figure 4-3 shows the operation of the MIC45212 during
a load transient. The output voltage drops due to the
sudden load increase, which causes the VFB to be less
than VREF. This will cause the error comparator to trigger an ON-time period. At the end of the ON-time
period, a minimum OFF-time, tOFF(MIN), is generated to
charge the Bootstrap Capacitor (CBST) since the feedback voltage is still below VREF. Then, the next ON-time
period is triggered due to the low feedback voltage.
Therefore, the switching frequency changes during the
load transient, but returns to the nominal fixed
frequency once the output has stabilized at the new
load current level. With the varying duty cycle and
switching frequency, the output recovery time is fast
and the output voltage deviation is small. Note that the
instantaneous switching frequency during load transient remains bounded and cannot increase arbitrarily.
The minimum is limited by tON + tOFF(MIN). Because the
variation in VOUT is relatively limited during load transient,
tON stays virtually close to its steady-state value.
IOUT
Full Load
No Load
VOUT
VFB
VREF
DH
In order to meet the stability requirements, the
MIC45212 feedback voltage ripple should be in phase
with the inductor current ripple, and is large enough to
be sensed by the gM amplifier and the error comparator. The recommended feedback voltage ripple is
20 mV ~ 100 mV over full input voltage range. If a
low-ESR output capacitor is selected, then the feedback voltage ripple may be too small to be sensed by
the gM amplifier and the error comparator. Also, the
output voltage ripple and the feedback voltage ripple
are not necessarily in phase with the inductor current
ripple if the ESR of the output capacitor is very low. In
these cases, ripple injection is required to ensure
proper operation. Please refer to Section 5.5 “Ripple
Injection” in Section 5.0 “Application Information”
for more details about the ripple injection technique.
4.2
Discontinuous Mode
(MIC45212-1 only)
In Continuous mode, the inductor current is always
greater than zero; however, at light loads, the
MIC45212-1 is able to force the inductor current to
operate in Discontinuous mode. Discontinuous mode is
where the inductor current falls to zero, as indicated by
trace (IL) shown in Figure 4-4. During this period, the efficiency is optimized by shutting down all the non-essential
circuits and minimizing the supply current as the
switching frequency is reduced. The MIC45212-1
wakes up and turns on the high-side MOSFET when
the feedback voltage, VFB, drops below 0.8V.
The MIC45212-1 has a Zero-Crossing (ZC) comparator
that monitors the inductor current by sensing the
voltage drop across the low-side MOSFET during its
ON-time. If the VFB > 0.8V and the inductor current
goes slightly negative, then the MIC45212-1 automatically powers down most of the IC circuitry and goes into
a Low-Power mode.
Once the MIC45212-1 goes into Discontinuous mode,
both DL and DH are low, which turns off the high-side
and low-side MOSFETs. The load current is supplied
by the output capacitors and VOUT drops. If the drop of
VOUT causes VFB to go below VREF, then all the circuits
will wake-up into normal Continuous mode. First, the
bias currents of most circuits reduced during the
Discontinuous mode are restored, and then a tON pulse
is triggered before the drivers are turned on to avoid
any possible glitches. Finally, the high-side driver is
turned on. Figure 4-4 shows the control loop timing in
Discontinuous mode.
tOFF(MIN)
FIGURE 4-3:
Response.
DS20005607A-page 16
MIC45212 Load Transient
 2017 Microchip Technology Inc.
MIC45212-1/-2
4.4
IL Crosses 0 and VFB > 0.8
Discontinuous Mode Starts
IL
VFB < 0.8V, Wake-up from
Discontinuous Mode
Current Limit
The MIC45212 uses the RDS(ON) of the low-side
MOSFET and the external resistor, connected from the
ILIM pin to the SW node, to set the current limit.
0
VFB
MIC45212
VIN
VIN
VREF
BST
ZC
CIN
SW
SW
CS
R15
ILIM
FB
C15
DH
PGND
Estimated ON-Time
DL
FIGURE 4-4:
MIC45212-1 Control Loop
Timing (Discontinuous Mode).
During Discontinuous mode, the bias current of most
circuits is substantially reduced. As a result, the total
power supply current during Discontinuous mode is only
about 370 µA, allowing the MIC45212-1 to achieve high
efficiency in light load applications.
4.3
Soft Start
Soft start reduces the input power supply surge current
at start-up by controlling the output voltage rise time.
The input surge appears while the output capacitor is
charged up.
The MIC45212 implements an internal digital soft start
by making the 0.8V reference voltage, VREF, ramp from
0 to 100% in about 3 ms with 9.7 mV steps. Therefore,
the output voltage is controlled to increase slowly by a
staircase VFB ramp. Once the soft start cycle ends, the
related circuitry is disabled to reduce current consumption. PVDD must be powered up at the same time or
after VIN to make the soft start function correctly.
 2017 Microchip Technology Inc.
FIGURE 4-5:
Circuit.
MIC45212 Current-Limiting
In each switching cycle of the MIC45212, the inductor
current is sensed by monitoring the low-side MOSFET
in the OFF period. The Sensed Voltage, VILIM, is compared with the Power Ground (PGND) after a blanking
time of 150 ns. In this way, the drop voltage over the
resistor, R15 (VCL), is compared with the drop over the
bottom FET generating the short current limit. The
small Capacitor (C15) connected from the ILIM pin to
PGND filters the switching node ringing during the
OFF-time, allowing a better short limit measurement.
The time constant created by R15 and C15 should be
much less than the minimum OFF-time.
The VCL drop allows programming of the short limit
through the value of the Resistor (R15). If the absolute
value of the voltage drop on the bottom FET becomes
greater than VCL, and the VILIM falls below PGND, an
overcurrent is triggered causing the IC to enter Hiccup
mode. The hiccup mode sequence, including the soft
start, reduces the stress on the switching FETs, and
protects the load and supply for severe short
conditions.
The short-circuit current limit can be programmed by
using Equation 4-3.
DS20005607A-page 17
MIC45212-1/-2
EQUATION 4-3:
PROGRAMMING
CURRENT LIMIT
The peak-to-peak inductor current ripple is:
EQUATION 4-4:
(ICLIM + IL(PP)  0.5)  RDS(ON) + VCL_OFFSET
R15 =
ICL
Where:
ICLIM = Desired current limit
RDS(ON) = On resistance of low-side power
MOSFET, 6 m typically
VCL_OFFSET = Current-limit threshold (typical
absolute value is 14 mV per Table 1-1)
ICL = Current-limit source current (typical value is
70 µA per Table 1-1)
IL(PP) = Inductor current peak-to-peak; since the
inductor is integrated, use Equation 4-4 to calculate
the inductor ripple current
IL(PP) =
PEAK-TO-PEAK
INDUCTOR CURRENT
RIPPLE
VOUT  (VIN(MAX) – VOUT)
VIN(MAX)  fSW  L
The MIC45212 has a 0.6 µH inductor integrated into
the module. In case of a hard short, the short limit is
folded down to allow an indefinite hard short on the output without any destructive effect. It is mandatory to
make sure that the inductor current used to charge the
output capacitance during soft start is under the folded
short limit; otherwise, the supply will go into hiccup
mode and may not finish the soft start successfully.
The MOSFET RDS(ON) varies 30% to 40% with
temperature; therefore, it is recommended to add a
50% margin to ICLIM in Equation 4-3 to avoid false
current limiting due to increased MOSFET junction
temperature rise.
With R15 = 1.69 k and C15 = 15 pF, the typical output
current limit is 16.8A.
DS20005607A-page 18
 2017 Microchip Technology Inc.
MIC45212-1/-2
5.0
APPLICATION INFORMATION
5.1
Setting the Switching Frequency
The MIC45212 switching frequency can be adjusted by
changing the value of resistors, R1 and R2.
MIC45212
VIN
BST
CIN
SW
CS
5.2
Output Capacitor Selection
The type of output capacitor is usually determined by
the application and its Equivalent Series Resistance
(ESR). Voltage and RMS current capability are two
other important factors for selecting the output capacitor. Recommended capacitor types are MLCC,
OS-CON and POSCAP. The output capacitor’s ESR is
usually the main cause of the output ripple. The
MIC45212 requires ripple injection and the output
capacitor ESR affects the control loop from a stability
point of view.
The maximum value of ESR is calculated as in
Equation 5-2:
EQUATION 5-2:
ESR MAXIMUM VALUE
R1
ESRCOUT 
FREQ
R2
FB
PGND
VOUT(PP)
IL(PP)
Where:
VOUT(PP) = Peak-to-peak output voltage ripple
FIGURE 5-1:
Adjustment.
Switching Frequency
Equation 5-1 gives the estimated switching frequency:
EQUATION 5-1:
ESTIMATED SWITCHING
FREQUENCY
IL(PP) = Peak-to-peak inductor current ripple
The total output ripple is a combination of the ESR and
output capacitance. The total ripple is calculated in
Equation 5-3:
EQUATION 5-3:
R2
fSW = fO 
R1 + R2
VOUT(PP) =
Where:
fO = 600 kHz (typical per TABLE 1-1: “Electrical
Characteristics(1)” table)
TOTAL OUTPUT RIPPLE
IL(PP)
2
2 + (I
L(PP)  ESRCOUT)

f

8

OUT
SW
C
R1 = 100 k is recommended
Where:
R2 = Needs to be selected in order to set the
required switching frequency
fSW = Switching frequency
FIGURE 5-2:
COUT = Output capacitance value
Switching Frequency vs. R2.
 2017 Microchip Technology Inc.
DS20005607A-page 19
MIC45212-1/-2
As described in Section 4.1 “Theory of Operation” in
Section 4.0 “Functional Description”, the MIC45212
requires at least a 20 mV peak-to-peak ripple at the FB
pin to make the gM amplifier and the error comparator
behave properly. Also, the output voltage ripple should
be in phase with the inductor current. Therefore, the
output voltage ripple caused by the output capacitors’
value should be much smaller than the ripple caused
by the output capacitor, ESR. If low-ESR capacitors,
such as ceramic capacitors, are selected as the output
capacitors, a ripple injection method should be applied
to provide enough feedback voltage ripple. Please refer
to Section 5.5 “Ripple Injection” in Section 5.0
“Application Information” for more details.
The output capacitor RMS current is calculated in
Equation 5-4:
EQUATION 5-4:
12
DISSIPATED POWER IN
OUTPUT CAPACITOR
PDISS(COUT) = ICOUT(RMS) ESRCOUT
2
Input Capacitor Selection
POWER DISSIPATED IN
INPUT CAPACITOR
PDISS(CIN(RMS)) = ICIN(RMS)2  ESRCIN
The general rule is to pick the capacitor with a ripple
current rating equal to or greater than the calculated
worst-case RMS capacitor current.
Equation 5-9 should be used to calculate the input
capacitor. Also, it is recommended to keep some
margin on the calculated value:
EQUATION 5-9:
INPUT CAPACITOR
CALCULATION
I
(1 – D)
CIN  OUT(MAX)
fSW  dV
IL(PP)
The power dissipated in the output capacitor is:
5.3
EQUATION 5-8:
OUTPUT CAPACITOR
RMS CURRENT
ICOUT(RMS) =
EQUATION 5-5:
The power dissipated in the input capacitor is:
Where:
dV = Input ripple
fSW = Switching frequency
5.4
Output Voltage Setting
Components
The MIC45212 requires two resistors to set the output
voltage, as shown in Figure 5-3:
The input capacitor for the Power Stage Input, PVIN,
should be selected for ripple current rating and voltage
rating. The input voltage ripple will primarily depend on
the input capacitor’s ESR. The peak input current is
equal to the peak inductor current, so:
RFB1
gM AMP
EQUATION 5-6:
FB
CONFIGURING RIPPLE
CURRENT AND VOLTAGE
RATINGS
RFB2
VIN = IL(pk)  ESRCIN
VREF
The input capacitor must be rated for the input current
ripple. The RMS value of input capacitor current is
determined at the maximum output current. Assuming
the peak-to-peak inductor current ripple is low:
EQUATION 5-7:
RMS VALUE OF INPUT
CAPACITOR CURRENT
FIGURE 5-3:
Configuration.
Voltage/Divider
ICIN(RMS) IOUT(MAX)D(1 – D)
Where:
D = Duty cycle
DS20005607A-page 20
 2017 Microchip Technology Inc.
MIC45212-1/-2
The output voltage is determined by Equation 5-10:
The applications are divided into two situations according
to the amount of the feedback voltage ripple:
EQUATION 5-10:
1.
OUTPUT VOLTAGE
DETERMINATION
Enough ripple at the feedback voltage due to the
large ESR of the output capacitors:
As shown in Figure 5-4, the converter is stable
without any ripple injection.
RFB1 
VOUT = VFB  1 +
RFB2 

Where:
VFB = 0.8V
VOUT
RFB1
A typical value of RFB1 used on the standard evaluation
board is 10 k. If RFB1 is too large, it may allow noise
to be introduced into the voltage feedback loop. If RFB1
is too small in value, it will decrease the efficiency of the
power supply, especially at light loads. Once RFB1 is
selected, RFB2 can be calculated using Equation 5-11:
EQUATION 5-11:
CALCULATING RFB2
RFB2 =
VFB  RFB1
VOUT – VFB
MIC45212
5.5
FIGURE 5-4:
ESR.
Enough Ripple at FB from
The feedback voltage ripple is:
EQUATION 5-12:
VFB(PP) 
RFB2
VOUT
OPEN
0.8V
40.2 k
1.0V
20 k
1.2V
11.5 k
1.5V
8.06 k
1.8V
4.75 k
2.5V
3.24 k
3.3V
1.91 k
5.0V
Ripple Injection
The VFB ripple required for proper operation of the
MIC45212 gM amplifier and error comparator is 20 mV
to 100 mV. However, the output voltage ripple is generally too small to provide enough ripple amplitude at the
FB pin and this issue is more visible in lower output
voltage applications. If the feedback voltage ripple is so
small that the gM amplifier and error comparator cannot
sense it, then the MIC45212 will lose control and the
output voltage is not regulated. In order to have some
amount of VFB ripple, a ripple injection method is
applied for low output voltage ripple applications.
FEEDBACK VOLTAGE
RIPPLE
RFB2
RFB1  RFB2
 ESRCOUT  IL(PP)
Where:
VOUT PROGRAMMING
RESISTOR LOOK-UP
 2017 Microchip Technology Inc.
COUT
ESR
RFB2
For fixed RFB1 = 10 k, the output voltage can be
selected by RFB2. Table 5-1 provides RFB2 values for
some common output voltages.
TABLE 5-1:
FB
IL(PP) = The peak-to-peak value of the inductor
current ripple
2.
There is virtually inadequate or no ripple at the
FB pin voltage due to the very low-ESR of the
output capacitors; such is the case with the
ceramic output capacitor. In this case, the VFB
ripple waveform needs to be generated by
injecting a suitable signal. MIC45212 has provisions to enable an internal series RC injection
network, RINJ and CINJ, as shown in Figure 5-5,
by connecting RIB to the FB pin. This network
injects a square wave current waveform into the
FB pin, which by means of integration across the
capacitor (C14), generates an appropriate
sawtooth FB ripple waveform.
VOUT
MIC45212
FB
RFB1
C14
COUT
RIB
RINJ
CINJ
RIA
RFB2
ESR
SW
FIGURE 5-5:
FB via RIB Pin.
Internal Ripple Injection at
DS20005607A-page 21
MIC45212-1/-2
The injected ripple is:
EQUATION 5-13:
INJECTED RIPPLE
VFB(PP) VIN  Kdiv  D  (1 – D) 
Kdiv =
RFB1//RFB2
RINJ + RFB1//RFB2
Where:
VIN = Power stage input voltage
D = Duty cycle
fSW = Switching frequency
1
fSW  
In Equation 5-13 and Equation 5-14, it is assumed that
the time constant associated with C14 must be much
greater than the switching period:
EQUATION 5-14:
CONDITION ON TIME
CONSTANT OF C14
1
T
=
<<1
fSW 

If the voltage divider resistors, RFB1 and RFB2, are in
the k range, then a C14 of 1 nF to 100 nF can easily
satisfy the large time constant requirements.
 = (RFB1//RFB2//RINJ)  C14
RINJ = 10 k
CINJ = 0.1 µF
DS20005607A-page 22
 2017 Microchip Technology Inc.
MIC45212-1/-2
5.6
Thermal Measurements and Safe
Operating Area (SOA)
Measuring the IC’s case temperature is recommended
to ensure it is within its operating limits. Although this
might seem like a very elementary task, it is easy to get
erroneous results. The most common mistake is to use
the standard thermal couple that comes with a thermal
meter. This thermal couple wire gauge is large, typically
22 gauge, and behaves like a heat sink, resulting in a
lower case measurement.
Two methods of temperature measurement are using a
smaller thermal couple wire or an infrared thermometer.
If a thermal couple wire is used, it must be constructed of
36-gauge wire or higher (smaller wire size) to minimize
the wire heat sinking effect. In addition, the thermal
couple tip must be covered in either thermal grease or
thermal glue to make sure that the thermal couple
junction is making good contact with the case of the
IC. Omega® Engineering brand thermal couple
(5SC-TT-K-36-36) is adequate for most applications.
FIGURE 5-6:
MIC45212 Power Derating
vs. Airflow (5 VIN to 1.5 VOUT).
Wherever possible, an infrared thermometer is recommended. The measurement spot size of most infrared
thermometers is too large for an accurate reading on a
small form factor IC. However, an IR thermometer from
Optris® has a 1 mm spot size, which makes it a good
choice for measuring the hottest point on the case. An
optional stand makes it easy to hold the beam on the IC
for long periods of time.
The Safe Operating Area (SOA) of the MIC45212 is
shown in Figure 5-6 through Figure 5-10. These thermal
measurements were taken on the MIC45212 evaluation
board. Since the MIC45212 is an entire system comprised of a switching regulator controller, MOSFETs and
inductor, the part needs to be considered as a system.
The SOA curves will give guidance to reasonable use of
the MIC45212.
FIGURE 5-7:
MIC45212 Power Derating
vs. Airflow (12 VIN to 1.5 VOUT).
SOA curves should only be used as a point of reference. SOA data was acquired using the MIC45212
evaluation board. Thermal performance depends on
the PCB layout, board size, copper thickness, number
of thermal vias and actual airflow.
FIGURE 5-8:
MIC45212 Power Derating
vs. Airflow (12 VIN to 3.3 VOUT).
 2017 Microchip Technology Inc.
DS20005607A-page 23
MIC45212-1/-2
FIGURE 5-9:
MIC45212 Power Derating
vs. Airflow (24 VIN to 1.5 VOUT).
DS20005607A-page 24
FIGURE 5-10:
MIC45212 Power Derating
vs. Airflow (24 VIN to 3.3 VOUT).
 2017 Microchip Technology Inc.
MIC45212-1/-2
6.0
PACKAGING INFORMATION
6.1
Package Marking Information
64-Lead 12 mm x 12 mm B2QFN
MIC
XXXXX-XXXX
WNNN
64-Lead 12 mm x 12 mm B2QFN
MIC
XXXXX-XXXX
WNNN
Legend: XX...X
Y
YY
WW
NNN
e3
*
Example
MIC
45212-1YMP
1256
Example
MIC
45212-2YMP
1256
Product code or customer-specific information
Year code (last digit of calendar year)
Year code (last 2 digits of calendar year)
Week code (week of January 1 is week ‘01’)
Alphanumeric traceability code
Pb-free JEDEC® designator for Matte Tin (Sn)
This package is Pb-free. The Pb-free JEDEC designator ( e3 )
can be found on the outer packaging for this package.
●, ▲, ▼ Pin one index is identified by a dot, delta up, or delta down (triangle
mark).
Note:
In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line, thus limiting the number of available
characters for customer-specific information. Package may or may not include
the corporate logo.
Underbar (_) and/or Overbar (⎯) symbol may not be to scale.
 2017 Microchip Technology Inc.
DS20005607A-page 25
MIC45212-1/-2
6.2
Package Details
The following sections give the technical details of the package.
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging.
DRAWING # B2QFN1212-64LD-PL-1
Lead Frame Copper
DS20005607A-page 26
UNIT MM
Lead Finish Matte Tin
 2017 Microchip Technology Inc.
MIC45212-1/-2
 2017 Microchip Technology Inc.
DS20005607A-page 27
MIC45212-1/-2
DS20005607A-page 28
 2017 Microchip Technology Inc.
MIC45212-1/-2
6.3
Note:
Thermally Enhanced Landing Pattern
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging.
 2017 Microchip Technology Inc.
DS20005607A-page 29
MIC45212-1/-2
6.3
Note:
Thermally Enhanced Landing Pattern (Continued)
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging.
DS20005607A-page 30
 2017 Microchip Technology Inc.
MIC45212-1/-2
APPENDIX A:
REVISION HISTORY
Revision A (November 2017)
• Converted Micrel document MIC45212-1/-2 to
Microchip data sheet DS20005607A.
• Minor text changes throughout document.
 2017 Microchip Technology Inc.
DS20005607A-page 31
MIC45212-1/-2
NOTES:
DS20005607A-page 32
 2017 Microchip Technology Inc.
MIC45212-1/-2
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, contact your local Microchip representative or sales office.
PART NO.
Device
–
XXX –
X
Option
Package
XX
Media
Type
Examples:
a) MIC45212-1YMP-T1: MIC45212, HLL,
64-Pin B2QFN, 100/Reel
b) MIC45212-1YMP-TR: MIC45212, HLL,
64-Pin B2QFN, 750/Reel
Device:
MIC45212:
Option:
1
2
26V, 14A DC-to-DC Power Module
c)
MIC45212-2YMP-T1: MIC45212,HSC,
64-Pin B2QFN, 100/Reel
=
=
HLL
HSC
Package:
YMP =
64-Pin 12 mm x 12 mm B2QFN
Media Type:
T1
TR
100/Reel
750/Reel
=
=
 2017 Microchip Technology Inc.
d) MIC45212-2YMP-TR: MIC45212,HSC,
64-Pin B2QFN, 750/Reel
DS20005607A-page 33
MIC45212-1/-2
NOTES:
DS20005607A-page 34
 2017 Microchip Technology Inc.
Note the following details of the code protection feature on Microchip devices:
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
•
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
•
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device
applications and the like is provided only for your convenience
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
MICROCHIP MAKES NO REPRESENTATIONS OR
WARRANTIES OF ANY KIND WHETHER EXPRESS OR
IMPLIED, WRITTEN OR ORAL, STATUTORY OR
OTHERWISE, RELATED TO THE INFORMATION,
INCLUDING BUT NOT LIMITED TO ITS CONDITION,
QUALITY, PERFORMANCE, MERCHANTABILITY OR
FITNESS FOR PURPOSE. Microchip disclaims all liability
arising from this information and its use. Use of Microchip
devices in life support and/or safety applications is entirely at
the buyer’s risk, and the buyer agrees to defend, indemnify and
hold harmless Microchip from any and all damages, claims,
suits, or expenses resulting from such use. No licenses are
conveyed, implicitly or otherwise, under any Microchip
intellectual property rights unless otherwise stated.
Microchip received ISO/TS-16949:2009 certification for its worldwide
headquarters, design and wafer fabrication facilities in Chandler and
Tempe, Arizona; Gresham, Oregon and design centers in California
and India. The Company’s quality system processes and procedures
are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping
devices, Serial EEPROMs, microperipherals, nonvolatile memory and
analog products. In addition, Microchip’s quality system for the design
and manufacture of development systems is ISO 9001:2000 certified.
QUALITY MANAGEMENT SYSTEM
CERTIFIED BY DNV
Trademarks
The Microchip name and logo, the Microchip logo, AnyRate, AVR,
AVR logo, AVR Freaks, BeaconThings, BitCloud, CryptoMemory,
CryptoRF, dsPIC, FlashFlex, flexPWR, Heldo, JukeBlox, KEELOQ,
KEELOQ logo, Kleer, LANCheck, LINK MD, maXStylus,
maXTouch, MediaLB, megaAVR, MOST, MOST logo, MPLAB,
OptoLyzer, PIC, picoPower, PICSTART, PIC32 logo, Prochip
Designer, QTouch, RightTouch, SAM-BA, SpyNIC, SST, SST
Logo, SuperFlash, tinyAVR, UNI/O, and XMEGA are registered
trademarks of Microchip Technology Incorporated in the U.S.A.
and other countries.
ClockWorks, The Embedded Control Solutions Company,
EtherSynch, Hyper Speed Control, HyperLight Load, IntelliMOS,
mTouch, Precision Edge, and Quiet-Wire are registered
trademarks of Microchip Technology Incorporated in the U.S.A.
Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any
Capacitor, AnyIn, AnyOut, BodyCom, chipKIT, chipKIT logo,
CodeGuard, CryptoAuthentication, CryptoCompanion,
CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average
Matching, DAM, ECAN, EtherGREEN, In-Circuit Serial
Programming, ICSP, Inter-Chip Connectivity, JitterBlocker,
KleerNet, KleerNet logo, Mindi, MiWi, motorBench, MPASM, MPF,
MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach,
Omniscient Code Generation, PICDEM, PICDEM.net, PICkit,
PICtail, PureSilicon, QMatrix, RightTouch logo, REAL ICE, Ripple
Blocker, SAM-ICE, Serial Quad I/O, SMART-I.S., SQI,
SuperSwitcher, SuperSwitcher II, Total Endurance, TSHARC,
USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, and
ZENA are trademarks of Microchip Technology Incorporated in the
U.S.A. and other countries.
SQTP is a service mark of Microchip Technology Incorporated in
the U.S.A.
Silicon Storage Technology is a registered trademark of Microchip
Technology Inc. in other countries.
GestIC is a registered trademark of Microchip Technology
Germany II GmbH & Co. KG, a subsidiary of Microchip Technology
Inc., in other countries.
All other trademarks mentioned herein are property of their
respective companies.
© 2017, Microchip Technology Incorporated, All Rights Reserved.
ISBN: 978-1-5224-2360-7
== ISO/TS 16949 ==
 2017 Microchip Technology Inc.
DS20005607A-page 35
NOTES:
DS20005607A-page 36
 2017 Microchip Technology Inc.
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 2017 Microchip Technology Inc.
10/25/17
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