MICROCHIP MCP4431

MCP444X/446X
7/8-Bit Quad I2C Digital POT with
Nonvolatile Memory
© 2010 Microchip Technology Inc.
MCP44X1 Quad Potentiometers
P3A
P3W
P3B
HVC/A0
SCL
SDA
VSS
P1B
P1W
P1A
20
19
18
17
16
15
14
12
12
11
1
2
3
4
5
6
7
8
9
10
P2A
P2W
P2B
VDD
A1
RESET
WP
P0B
P0W
P0A
P2B
P2W
P2A
P3A
P3W
TSSOP
20 19 18 17 16
1
3
SDA
4
VSS
5
VDD
EP
21
6
7
8
13
RESET
12
WP
11
P0B
9 10
P0W
2
SCL
P0A
HVC/A0
15
14 A1
P1A
P3B
P1B
• Quad Resistor Network
• Potentiometer or Rheostat configuration options
• Resistor Network Resolution
- 7-bit: 128 Resistors (129 Taps)
- 8-bit: 256 Resistors (257 Taps)
• RAB Resistances options of:
- 5 kΩ
- 10 kΩ
- 50 kΩ
- 100 kΩ
• Zero Scale to Full Scale Wiper operation
• Low Wiper Resistance: 75 Ω (typical)
• Low Tempco:
- Absolute (Rheostat): 50 ppm typical
(0°C to 70°C)
- Ratiometric (Potentiometer): 15 ppm typical
• Nonvolatile Memory
- Automatic Recall of Saved Wiper Setting
- WiperLock™ Technology
- 5 General Purpose Memory Locations
• I2C Serial Interface
- 100 kHz, 400 kHz, and 3.4 MHz support
• Serial protocol allows:
- High-Speed Read/Write to wiper
- Read/Write to EEPROM
- Write Protect to be enabled/disable
- WiperLock to be enabled/disabled
• Resistor Network Terminal Disconnect Feature
via Terminal Control (TCON) Register
• Reset input pin
• Write Protect Feature:
- Hardware Write Protect (WP) Control pin
- Software Write Protect (WP) Configuration bit
• Brown-out reset protection (1.5V typical)
• Serial Interface Inactive current (2.5 uA typical)
• High-Voltage Tolerant Digital Inputs: Up to 12.5V
• Supports Split Rail Applications
• Internal weak pull-up on all digital inputs
(except SCL and SDA)
• Wide Operating Voltage:
- 2.7V to 5.5V - Device Characteristics
Specified
- 1.8V to 5.5V - Device Operation
• Wide Bandwidth (-3 dB) Operation:
- 2 MHz (typical) for 5.0 kΩ device
• Extended temperature range (-40°C to +125°C)
• Package Types: 4x4 QFN-20, TSSOP-20 and
TSSOP-14
Package Types (Top View)
P1W
Features
4x4 QFN
MCP44X2 Quad Rheostat
P3W
P3B
HVC/A0
SCL
SDA
VSS
P1B
1
2
3
4
5
6
7
14
13
12
11
10
9
8
P2W
P2B
VDD
A1
P0B
P0W
P1W
TSSOP
DS22265A-page 1
MCP444X/446X
Device Block Diagram
VDD
Power-up/
Brown-out
Control
VSS
WP
RESET
P0W
Wiper 0
& TCON0
Register
I2C Serial
Interface
Module &
Control
Logic
(WiperLock™
Technology)
A1
HVC/A0
SCL
SDA
P0A
Resistor
Network 0
(Pot 0)
P0B
P1A
Resistor
Network 1
(Pot 1)
P1W
Wiper 1
& TCON0
Register
Memory (16x9)
Wiper0 (V & NV)
Wiper1 (V & NV)
Wiper2 (V & NV)
Wiper3 (V & NV)
P1B
P2A
Resistor
Network 2
(Pot 2)
TCON0
TCON1
STATUS
Data EEPROM
(5 x 9-bits)
P2W
Wiper 2
& TCON1
Register
P2B
P3A
Resistor
Network 3
(Pot 3)
P3W
Wiper 3
& TCON1
Register
P3B
No
Mid-Scale 5.0, 10.0, 50.0, 100.0
75
129 1.8V to 5.5V
4
I2C
RAM
No
Mid-Scale 5.0, 10.0, 50.0, 100.0
75
129 1.8V to 5.5V
2
Rheostat
(1)
Resistance (typical)
RAB Options (kΩ)
Wiper
- RW
(Ω)
# of Taps
RAM
MCP4432 (3)
Wiper
Configuration
POR Wiper
Setting
WiperLock
Technology
4 Potentiometer (1) I2C
Device
Control
MCP4431(3)
# of POTs
Memory
Type
Device Features
VDD
Operating
Range(2)
MCP4441
4 Potentiometer
I C
EE
Yes
NV Wiper 5.0, 10.0, 50.0, 100.0
75
129 2.7V to 5.5V
MCP4442
4
Rheostat
I2C
EE
Yes
NV Wiper 5.0, 10.0, 50.0, 100.0
75
129 2.7V to 5.5V
MCP4451(3)
4
Potentiometer(1)
I2C
RAM
No
Mid-Scale 5.0, 10.0, 50.0, 100.0
75
257 1.8V to 5.5V
MCP4452(3)
4
Rheostat
I2C
RAM
No
Mid-Scale 5.0, 10.0, 50.0, 100.0
75
257 1.8V to 5.5V
MCP4461
4
Potentiometer(1)
I2C
EE
Yes
NV Wiper 5.0, 10.0, 50.0, 100.0
75
257 2.7V to 5.5V
MCP4462
4
Rheostat
I2C
EE
Yes
NV Wiper 5.0, 10.0, 50.0, 100.0
75
257 2.7V to 5.5V
Note 1:
2:
3:
Floating either terminal (A or B) allows the device to be used as a Rheostat (variable resistor).
Analog characteristics only tested from 2.7V to 5.5V unless otherwise noted.
Please check Microchip web site for device release and availability.
DS22265A-page 2
© 2010 Microchip Technology Inc.
MCP444X/446X
1.0
ELECTRICAL
CHARACTERISTICS
Absolute Maximum Ratings †
Voltage on VDD with respect to VSS ................ -0.6V to +7.0V
Voltage on HVC/A0, A1, SCL, SDA, WP, and
RESET with respect to VSS ................................... -0.6V to 12.5V
Voltage on all other pins (PxA, PxW, and PxB)
with respect to VSS ......................................... -0.3V to VDD + 0.3V
Input clamp current, IIK
(VI < 0, VI > VDD, VI > VPP ON HV pins) ......................±20 mA
Output clamp current, IOK
(VO < 0 or VO > VDD) ..................................................±20 mA
Maximum output current sunk by any Output pin
......................................................................................25 mA
Maximum output current sourced by any Output pin ed
......................................................................................25 mA
Maximum current out of VSS pin .................................100 mA
Maximum current into VDD pin ....................................100 mA
Maximum current into PXA, PXW & PXB pins ............±2.5 mA
Storage temperature ....................................-65°C to +150°C
Ambient temperature with power applied
..................................................................... -40°C to +125°C
Package power dissipation (TA = +50°C, TJ = +150°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 listings of this specification is not implied.
Exposure to maximum rating conditions for extended periods
may affect device reliability.
TSSOP-14....................................................... 1000 mW
TSSOP-20....................................................... 1110 mW
QFN-20 (4x4) .................................................. 2320 mW
Soldering temperature of leads (10 seconds) ............. +300°C
ESD protection on all pins ................................... ≥ 4 kV (HBM),
.......................................................................... ≥ 300V (MM)
Maximum Junction Temperature (TJ) ......................... +150°C
© 2010 Microchip Technology Inc.
DS22265A-page 3
MCP444X/446X
AC/DC CHARACTERISTICS
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Parameters
Sym
Min
Typ
Max
Units
Supply Voltage
VDD
HVC/A0, SDA,
SCL, A1, WP,
RESET pin
Voltage Range
VHV
2.7
1.8
VSS
—
—
—
5.5
2.7
12.5V
V
V
V
VSS
—
V
—
—
VDD +
8.0V
1.65
VDD Start Voltage
to ensure Wiper
Reset
VDD Rise Rate to
ensure Power-on
Reset
Delay after device
exits the reset
state
(VDD > VBOR)
Supply Current
(Note 10)
VBOR
VDDRR
(Note 9)
V
Conditions
Serial Interface only.
VDD ≥ The HVC/A0 pin will be at one
4.5V
of three input levels
VDD < (VIL, VIH or VIHH). (Note 6)
4.5V
RAM retention voltage (VRAM) < VBOR
V/ms
TBORD
—
10
20
µs
IDD
—
—
600
µA
Serial Interface Active,
HVC/A0 = VIH (or VIL) (Note 11)
Write all 0’s to volatile Wiper 0
VDD = 5.5V, FSCL @ 3.4 MHz
—
—
250
µA
Serial Interface Active,
HVC/A0 = VIH (or VIL) (Note 11)
Write all 0’s to volatile Wiper 0
VDD = 5.5V, FSCL @ 100 kHz
—
—
575
µA
EE Write Current (Write Cycle)
(Nonvolatile device only),
VDD = 5.5V, FSCL = 400 kHz,
Write all 0’s to Nonvolatile Wiper 0
SCL = VIL or VIH
—
2.5
5
µA
Serial Interface Inactive,
(Stop condition, SCL = SDA = VIH),
Wiper = 0
VDD = 5.5V, HVC/A0 = VIH
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
DS22265A-page 4
© 2010 Microchip Technology Inc.
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
Parameters
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Sym
Min
Typ
Max
Units
Resistance
(± 20%)
RAB
4.0
8.0
40.0
80.0
6.0
12.0
60.0
120.0
Resolution
N
Step Resistance
RS
5
10
50
100
257
129
RAB /
(256)
RAB /
(128)
0.2
0.2
0.2
0.2
0.25
0.25
0.25
0.25
75
75
50
100
150
15
—
kΩ
kΩ
kΩ
kΩ
Taps
Taps
Ω
—
Ω
1.50
1.25
1.0
1.0
1.75
1.50
1.25
1.25
160
300
—
—
—
—
%
%
%
%
%
%
%
%
Ω
Ω
ppm/°C
ppm/°C
ppm/°C
ppm/°C
—
—
Nominal
Resistance Match
(| RABWC RABMEAN |) /
RABMEAN
(| RBWWC RBWMEAN |) /
RBWMEAN
Wiper Resistance
(Note 3, Note 4)
Nominal
Resistance
Tempco
RW
ΔRAB/ΔT
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Conditions
-502 devices (Note 1)
-103 devices (Note 1)
-503 devices (Note 1)
-104 devices (Note 1)
8-bit
No Missing Codes
7-bit
No Missing Codes
8-bit
Note 6
7-bit
Note 6
5 kΩ
MCP44X1 devices only
10 kΩ
50 kΩ
100 kΩ
5 kΩ
Code = Full Scale
10 kΩ
50 kΩ
100 kΩ
VDD = 5.5 V, IW = 2.0 mA, code = 00h
VDD = 2.7 V, IW = 2.0 mA, code = 00h
TA = -20°C to +70°C
TA = -40°C to +85°C
TA = -40°C to +125°C
Code = Midscale (80h or 40h)
Ratiometeric
ΔVWB/ΔT
Tempco
Resistance
ΔRTRACK
Section 2.0
ppm/°C See Typical Performance Curves
Tracking
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
© 2010 Microchip Technology Inc.
DS22265A-page 5
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Parameters
Sym
Min
Typ
Max
Units
Resistor Terminal
Input Voltage
Range (Terminals
A, B and W)
Maximum current
through A, W or B
(Note 6)
VA,VW,VB
Vss
—
VDD
V
IW
—
—
2.5
mA
Terminal A
IAW,
W = Full Scale (FS)
—
—
2.5
mA
Terminal B
IBW,
W = Zero Scale (ZS)
—
—
2.5
mA
Terminal W
IAW (W = FS) or
IBW (W = ZS)
—
—
—
—
—
—
—
—
—
—
—
100
100
100
1.38
0.688
0.138
0.069
—
—
—
mA
mA
mA
mA
nA
nA
nA
Maximum RAB
current (IAB)
(Note 6)
IAB
Conditions
Note 5, Note 6
VB = 0V, VA = 5.5V, RAB(MIN) = 4000Ω
VB = 0V, VA = 5.5V, RAB(MIN) = 8000Ω
VB = 0V, VA = 5.5V, RAB(MIN) = 40000Ω
VB = 0V, VA = 5.5V, RAB(MIN) = 80000Ω
Leakage current
IWL
MCP44X1 PxA = PxW = PxB = VSS
into A, W or B
MCP44X2 PxB = PxW = VSS
Terminals Disconnected
(R0A = R0W = R0B = 0;
R1A = R1W = R1B = 0;
R2A = R2W = R2B = 0;
R3A = R3W = R3B = 0)
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
DS22265A-page 6
© 2010 Microchip Technology Inc.
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
Parameters
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Sym
Min
Typ
Max
Units
Conditions
8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
10 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
50 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
100 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
Zero Scale Error
VWZSE
5 kΩ
8-bit
3.0V ≤ VDD ≤ 5.5V
(MCP44X1 only)
7-bit
3.0V ≤ VDD ≤ 5.5V
(8-bit code = 00h,
10 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit code = 00h)
7-bit
3.0V ≤ VDD ≤ 5.5V
50 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
100 kΩ 8-bit
3.0V ≤ VDD ≤ 5.5V
7-bit
3.0V ≤ VDD ≤ 5.5V
Potentiometer
INL
8-bit
3.0V ≤ VDD ≤ 5.5V
Integral
MCP44X1 devices only
7-bit
Non-linearity
(Note 2)
Potentiometer
DNL
-0.5
±0.25
+0.5
LSb
8-bit
3.0V ≤ VDD ≤ 5.5V
Differential NonMCP44X1 devices only
-0.25
±0.125
+0.25
LSb
7-bit
linearity
(Note 2)
Bandwidth -3 dB
BW
—
2
—
MHz 5 kΩ
8-bit
Code = 80h
(See Figure 2-72,
—
2
—
MHz
7-bit
Code = 40h
load = 30 pF)
—
1
—
MHz 10 kΩ 8-bit
Code = 80h
—
1
—
MHz
7-bit
Code = 40h
—
200
—
kHz
50 kΩ 8-bit
Code = 80h
—
200
—
kHz
7-bit
Code = 40h
—
100
—
kHz
100 kΩ 8-bit
Code = 80h
—
100
—
kHz
7-bit
Code = 40h
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
Full Scale Error
(MCP44X1 only)
(8-bit code = 100h,
7-bit code = 80h)
VWFSE
© 2010 Microchip Technology Inc.
-6.0
-4.0
-3.5
-2.0
-0.8
-0.5
-0.5
-0.5
—
—
—
—
—
—
—
—
-1
-0.5
-0.1
-0.1
-0.1
-0.1
-0.1
-0.1
-0.1
-0.1
+0.1
+0.1
+0.1
+0.1
+0.1
+0.1
+0.1
+0.1
±0.5
±0.25
—
—
—
—
—
—
—
—
+6.0
+3.0
+3.5
+2.0
+0.8
+0.5
+0.5
+0.5
+1
+0.5
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
LSb
5 kΩ
DS22265A-page 7
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Parameters
Sym
Min
Typ
Max
Units
Conditions
Rheostat Integral
Non-linearity
MCP44X1
(Note 4, Note 8)
MCP44X2 devices
only (Note 4)
R-INL
-1.5
-8.25
±0.5
+4.5
+1.5
+8.25
LSb
LSb
-1.125
-6.0
±0.5
+4.5
+1.125
+6.0
LSb
LSb
-1.5
-5.5
±0.5
+2.5
+1.5
+5.5
LSb
LSb
-1.125
-4.0
±0.5
+2.5
+1.125
+4.0
LSb
LSb
-1.5
-2.0
±0.5
+1
+1.5
+2.0
LSb
LSb
-1.125
-1.5
±0.5
+1
+1.125
+1.5
LSb
LSb
7-bit
-1.0
-1.5
±0.5
+0.25
+1.0
+1.5
LSb
LSb
100 kΩ 8-bit
-0.8
-1.125
±0.5
+0.25
+0.8
+1.125
LSb
LSb
7-bit
5 kΩ
8-bit
7-bit
10 kΩ
8-bit
7-bit
50 kΩ
8-bit
5.5V, IW = 900 µA
3.0V, IW = 480 µA
(Note 7)
5.5V, IW = 900 µA
3.0V, IW = 480 µA
(Note 7)
5.5V, IW = 450 µA
3.0V, IW = 240 µA
(Note 7)
5.5V, IW = 450 µA
3.0V, IW = 240 µA
(Note 7)
5.5V, IW = 90 µA
3.0V, IW = 48 µA
(Note 7)
5.5V, IW = 90 µA
3.0V, IW = 48 µA
(Note 7)
5.5V, IW = 45 µA
3.0V, IW = 24 µA
(Note 7)
5.5V, IW = 45 µA
3.0V, IW = 24 µA
(Note 7)
Resistance is defined as the resistance between terminal A to terminal B.
INL and DNL are measured at VW with VA = VDD and VB = VSS.
MCP44X1 only.
MCP44X2 only, includes VWZSE and VWFSE.
Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
This specification by design.
Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
Note 1:
2:
3:
4:
5:
6:
7:
DS22265A-page 8
© 2010 Microchip Technology Inc.
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Parameters
Sym
Rheostat
Differential Nonlinearity
MCP44X1
(Note 4, Note 8)
MCP44X2 devices
only
(Note 4)
R-DNL
Min
Typ
Max
Units
Conditions
5.5V, IW = 900 µA
3.0V, IW = 480 µA
(Note 7)
-0.375
±0.25
+0.375
LSb
7-bit
5.5V, IW = 900 µA
-0.75
+0.5
+0.75
LSb
3.0V, IW = 480 µA
(Note 7)
-0.5
±0.25
+0.5
LSb
10 kΩ 8-bit
5.5V, IW = 450 µA
-1.0
+0.25
+1.0
LSb
3.0V, IW = 240 µA
(Note 7)
-0.375
±0.25
+0.375
LSb
7-bit
5.5V, IW = 450 µA
-0.75
+0.5
+0.75
LSb
3.0V, IW = 240 µA
(Note 7)
-0.5
±0.25
+0.5
LSb
50 kΩ 8-bit
5.5V, IW = 90 µA
-0.5
±0.25
+0.5
LSb
3.0V, IW = 48 µA
(Note 7)
-0.375
±0.25
+0.375
LSb
7-bit
5.5V, IW = 90 µA
-0.375
±0.25
+0.375
LSb
3.0V, IW = 48 µA
(Note 7)
-0.5
±0.25
+0.5
LSb
100 kΩ 8-bit
5.5V, IW = 45 µA
-0.5
±0.25
+0.5
LSb
3.0V, IW = 24 µA
(Note 7)
-0.375
±0.25
+0.375
LSb
7-bit
5.5V, IW = 45 µA
-0.375
±0.25
+0.375
LSb
3.0V, IW = 24 µA
(Note 7)
CAW
—
75
—
pF
f =1 MHz, Code = Full Scale
Capacitance (PA)
Capacitance (Pw)
CW
—
120
—
pF
f =1 MHz, Code = Full Scale
Capacitance (PB)
CBW
—
75
—
pF
f =1 MHz, Code = Full Scale
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
© 2010 Microchip Technology Inc.
-0.5
-1.0
±0.25
+0.5
+0.5
+1.0
LSb
LSb
5 kΩ
8-bit
DS22265A-page 9
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
Parameters
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Sym
Min
Typ
Max
Digital Inputs/Outputs (HVC/A0, A1, SDA, SCL, WP, RESET)
Schmitt Trigger
VIH
0.45 VDD
—
—
High Input
Threshold
0.5 VDD
—
—
Units
V
V
Conditions
All
Inputs
except
SDA
and
SCL
2.7V ≤ VDD ≤ 5.5V
(Allows 2.7V Digital VDD with
5V Analog VDD)
1.8V ≤ VDD ≤ 2.7V
—
0.7 VDD
—
0.7 VDD
0.7 VDD
—
0.7 VDD
—
—
—
-0.5
—
-0.5
—
-0.5
—
-0.5
—
—
0.1VDD
N.A.
—
N.A.
—
0.1 VDD
—
0.05 VDD
—
0.1 VDD
—
0.1 VDD
—
9.0
—
VMAX
V
100 kHz
SDA
VMAX
V
400 kHz
and
VMAX
V
1.7 MHz
SCL
VMAX
V
3.4 Mhz
Schmitt Trigger
VIL
0.2VDD
V
All inputs except SDA and SCL
Low Input
0.3VDD
V
100 kHz
SDA 400 kHz
Threshold
0.3VDD
V
and
0.3VDD
V
SCL 1.7 MHz
0.3VDD
V
3.4 Mhz
Hysteresis of
VHYS
—
V
All inputs except SDA and SCL
Schmitt Trigger
—
V
VDD < 2.0V
100 kHz
Inputs
—
V
VDD ≥ 2.0V
SDA
—
V
VDD < 2.0V
and 400 kHz
—
V
VDD ≥ 2.0V
SCL
—
V
1.7 MHz
—
V
3.4 Mhz
High Voltage Input
VIHHEN
12.5
V
Threshold for WiperLock Technology
Entry Voltage
(Note 6)
—
—
VDD +
High Voltage Input
VIHHEX
V
0.8V
Exit Voltage
(Note 6)
—
—
12.5
V
Pin can tolerate VMAX or less.
High Voltage Limit
VMAX
(Note 6)
VSS
—
0.2VDD
V
VDD < 2.0V, IOL = 1 mA,
Output Low
VOL
Voltage (SDA)
VSS
—
0.4
V
VDD ≥ 2.0V, IOL = 3 mA
Note 1: Resistance is defined as the resistance between terminal A to terminal B.
2: INL and DNL are measured at VW with VA = VDD and VB = VSS.
3: MCP44X1 only.
4: MCP44X2 only, includes VWZSE and VWFSE.
5: Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
6: This specification by design.
7: Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
DS22265A-page 10
© 2010 Microchip Technology Inc.
MCP444X/446X
AC/DC CHARACTERISTICS (CONTINUED)
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
DC Characteristics
Parameters
Weak Pull-up
Current
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Sym
Min
Typ
Max
Units
IPU
—
—
1.75
mA
—
—
170
16
—
—
µA
kΩ
Internal VDD pull-up, VIHH pull-down,
VDD = 5.5V, VHVC = 12.5V
HVC pin, VDD = 5.5V, VHVC = 3V
VDD = 5.5V, VHVC = 3V
—
16
—
kΩ
VDD = 5.5V, VRESET = 0V
-1
—
1
µA
—
10
—
pF
VIN = VDD (all pins) and
VIN = VSS (all pins except RESET)
fC = 20 MHz
0h
0h
—
—
1FF
1FFh
1FFh
hex
hex
hex
8-bit device
7-bit device
All Terminals connected
—
0h
1M
—
080h
040h
000h
—
1FFh
Cycles
hex
hex
hex
hex
HVC Pull-up /
RHVC
Pull-down
Resistance
RESET Pull-up
RRESET
Resistance
Input Leakage
IIL
Current
Pin Capacitance
CIN, COUT
RAM (Wiper, TCON) Value
Value Range
N
TCON POR/BOR
Setting
EEPROM
Endurance
EEPROM Range
Initial NV Wiper
POR/BOR Setting
Initial EEPROM
POR/BOR Setting
EEPROM
Programming
Write Cycle Time
Power Requirements
Power Supply
Sensitivity
(MCP44X1)
Endurance
N
N
N
Conditions
8-bit
7-bit
WiperLock Technology = Off
WiperLock Technology = Off
VDD = 2.7V to 5.5V,
VA = 2.7V, Code = 80h
VDD = 2.7V to 5.5V,
VA = 2.7V, Code = 40h
tWC
—
3
10
ms
PSS
—
0.0015
0.0035
%/%
8-bit
—
0.0015
0.0035
%/%
7-bit
Resistance is defined as the resistance between terminal A to terminal B.
INL and DNL are measured at VW with VA = VDD and VB = VSS.
MCP44X1 only.
MCP44X2 only, includes VWZSE and VWFSE.
Resistor terminals A, W and B’s polarity with respect to each other is not restricted.
This specification by design.
Non-linearity is affected by wiper resistance (RW), which changes significantly over voltage and
temperature.
8: The MCP44X1 is externally connected to match the configurations of the MCP44X2, and then tested.
9: POR/BOR is not rate dependent.
10: Supply current is independent of current through the resistor network.
11: When HVC/A0 = VIHH, the IDD current is less due to current into the HVC/A0 pin. See IPU specification.
Note 1:
2:
3:
4:
5:
6:
7:
© 2010 Microchip Technology Inc.
DS22265A-page 11
MCP444X/446X
I2C Mode Timing Waveforms and Requirements
1.1
RESET
tRST
SCL
tRSTD
VIH
VIH
SDA
Wx
FIGURE 1-1:
TABLE 1-1:
RESET Waveforms.
RESET TIMING
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (extended)
Timing Characteristics
Parameters
All parameters apply across the specified operating ranges unless noted.
VDD = +2.7V to 5.5V, 5 kΩ, 10 kΩ, 50 kΩ, 100 kΩ devices.
Typical specifications represent values for VDD = 5.5V, TA = +25°C.
Sym
Min
Typ
Max
Units
RESET pulse width
tRST
50
—
—
ns
RESET rising edge
normal mode (Wiper
driving and I2C
interface operational)
tRSTD
—
—
20
ns
DS22265A-page 12
Conditions
© 2010 Microchip Technology Inc.
MCP444X/446X
VIHH
HVC/A0 VIH 94
or VIL
95
SCL
VIH or VIL
93
91
90
92
SDA
STOP
Condition
START
Condition
I2C Bus Start/Stop Bits Timing Waveforms.
FIGURE 1-2:
TABLE 1-2:
I2C BUS START/STOP BITS REQUIREMENTS
I2C AC Characteristics
Param.
Symbol
No.
FSCL
D102
90
91
92
93
94
95
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (Extended)
Operating Voltage VDD range is described in AC/DC characteristics
Characteristic
Standard Mode
Fast Mode
High-Speed 1.7
High-Speed 3.4
Cb
Bus capacitive
100 kHz mode
loading
400 kHz mode
1.7 MHz mode
3.4 MHz mode
TSU:STA START condition
100 kHz mode
Setup time
400 kHz mode
1.7 MHz mode
3.4 MHz mode
THD:STA START condition
100 kHz mode
Hold time
400 kHz mode
1.7 MHz mode
3.4 MHz mode
100 kHz mode
TSU:STO STOP condition
Setup time
400 kHz mode
1.7 MHz mode
3.4 MHz mode
THD:STO STOP condition
100 kHz mode
Hold time
400 kHz mode
1.7 MHz mode
3.4 MHz mode
THVCSU HVC to SCL Setup time
THVCHD SCL to HVC Hold time
© 2010 Microchip Technology Inc.
Min
Max
Units
0
0
0
0
—
—
—
—
4700
600
160
160
4000
600
160
160
4000
600
160
160
4000
600
160
160
25
25
100
400
1.7
3.4
400
400
400
100
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
kHz
kHz
MHz
MHz
pF
pF
pF
pF
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
uS
uS
Conditions
Cb = 400 pF, 1.8V - 5.5V
Cb = 400 pF, 2.7V - 5.5V
Cb = 400 pF, 4.5V - 5.5V
Cb = 100 pF, 4.5V - 5.5V
Only relevant for repeated
START condition
After this period the first
clock pulse is generated
High Voltage Commands
High Voltage Commands
DS22265A-page 13
MCP444X/446X
103
102
100
101
SCL
90
106
91
92
107
SDA
In
110
109
109
SDA
Out
I2C Bus Data Timing.
FIGURE 1-3:
I2C BUS DATA REQUIREMENTS (SLAVE MODE)
TABLE 1-3:
I2C AC Characteristics
Param.
No.
Sym
Characteristic
100
THIGH
Clock high time
101
Note 1:
2:
3:
4:
5:
6:
7:
TLOW
Clock low time
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (Extended)
Operating Voltage VDD range is described in AC/DC characteristics
Min
Max
Units
100 kHz mode
4000
—
ns
1.8V-5.5V
400 kHz mode
600
—
ns
2.7V-5.5V
1.7 MHz mode
120
ns
4.5V-5.5V
3.4 MHz mode
60
—
ns
4.5V-5.5V
100 kHz mode
4700
—
ns
1.8V-5.5V
400 kHz mode
1300
—
ns
2.7V-5.5V
ns
4.5V-5.5V
—
ns
4.5V-5.5V
1.7 MHz mode
320
3.4 MHz mode
160
Conditions
As a transmitter, the device must provide this internal minimum delay time to bridge the undefined region
(minimum 300 ns) of the falling edge of SCL to avoid unintended generation of START or STOP conditions.
A fast-mode (400 kHz) I2C-bus device can be used in a standard-mode (100 kHz) I2C-bus system, but the
requirement tSU;DAT ≥ 250 ns must then be met. This will automatically be the case if the device does not
stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal,
it must output the next data bit to the SDA line
TR max.+tSU;DAT = 1000 + 250 = 1250 ns (according to the standard-mode I2C bus specification) before
the SCL line is released.
The MCP44X1/MCP44X2 device must provide a data hold time to bridge the undefined part between VIH
and VIL of the falling edge of the SCL signal. This specification is not a part of the I2C specification, but
must be tested in order to ensure that the output data will meet the setup and hold specifications for the
receiving device.
Use Cb in pF for the calculations.
Not Tested.
A Master Transmitter must provide a delay to ensure that difference between SDA and SCL fall times do
not unintentionally create a Start or Stop condition.
Ensured by the TAA 3.4 MHz specification test.
DS22265A-page 14
© 2010 Microchip Technology Inc.
MCP444X/446X
TABLE 1-3:
I2C BUS DATA REQUIREMENTS (SLAVE MODE) (CONTINUED)
I2C AC Characteristics
Param.
No.
Sym
102A (5)
TRSCL
102B (5)
103A
103B
(5)
(5)
106
Note 1:
2:
3:
4:
5:
6:
7:
TRSDA
TFSCL
TFSDA
THD:DAT
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (Extended)
Operating Voltage VDD range is described in AC/DC characteristics
Characteristic
SCL rise time
SDA rise time
SCL fall time
SDA fall time
Data input hold
time
Min
Max
Units
Conditions
100 kHz mode
—
1000
ns
400 kHz mode
20 + 0.1Cb
300
ns
Cb is specified to be from
10 to 400 pF (100 pF maximum for 3.4 MHz mode)
1.7 MHz mode
20
80
ns
1.7 MHz mode
20
160
ns
3.4 MHz mode
10
40
ns
3.4 MHz mode
10
80
ns
After a Repeated Start
condition or an Acknowledge bit
100 kHz mode
—
1000
ns
Cb is specified to be from
10 to 400 pF (100 pF max
for 3.4 MHz mode)
400 kHz mode
20 + 0.1Cb
300
ns
1.7 MHz mode
20
160
ns
3.4 MHz mode
10
80
ns
100 kHz mode
—
300
ns
400 kHz mode
20 + 0.1Cb
300
ns
1.7 MHz mode
20
80
ns
3.4 MHz mode
10
40
ns
100 kHz mode
—
300
ns
400 kHz mode
20 + 0.1Cb (4)
300
ns
1.7 MHz mode
20
160
ns
3.4 MHz mode
10
80
ns
After a Repeated Start condition or an Acknowledge
bit
Cb is specified to be from
10 to 400 pF (100 pF max
for 3.4 MHz mode)
Cb is specified to be from
10 to 400 pF (100 pF max
for 3.4 MHz mode)
100 kHz mode
0
—
ns
1.8V-5.5V, Note 6
400 kHz mode
0
—
ns
2.7V-5.5V, Note 6
1.7 MHz mode
0
—
ns
4.5V-5.5V, Note 6
3.4 MHz mode
0
—
ns
4.5V-5.5V, Note 6
As a transmitter, the device must provide this internal minimum delay time to bridge the undefined region
(minimum 300 ns) of the falling edge of SCL to avoid unintended generation of START or STOP conditions.
A fast-mode (400 kHz) I2C-bus device can be used in a standard-mode (100 kHz) I2C-bus system, but the
requirement tSU;DAT ≥ 250 ns must then be met. This will automatically be the case if the device does not
stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal,
it must output the next data bit to the SDA line
TR max.+tSU;DAT = 1000 + 250 = 1250 ns (according to the standard-mode I2C bus specification) before
the SCL line is released.
The MCP44X1/MCP44X2 device must provide a data hold time to bridge the undefined part between VIH
and VIL of the falling edge of the SCL signal. This specification is not a part of the I2C specification, but
must be tested in order to ensure that the output data will meet the setup and hold specifications for the
receiving device.
Use Cb in pF for the calculations.
Not Tested.
A Master Transmitter must provide a delay to ensure that difference between SDA and SCL fall times do
not unintentionally create a Start or Stop condition.
Ensured by the TAA 3.4 MHz specification test.
© 2010 Microchip Technology Inc.
DS22265A-page 15
MCP444X/446X
I2C BUS DATA REQUIREMENTS (SLAVE MODE) (CONTINUED)
TABLE 1-3:
I2C AC Characteristics
Param.
No.
107
109
110
Sym
2:
3:
4:
5:
6:
7:
Characteristic
TSU:DAT Data input setup
time
TAA
TBUF
TSP
Note 1:
Standard Operating Conditions (unless otherwise specified)
Operating Temperature
–40°C ≤ TA ≤ +125°C (Extended)
Operating Voltage VDD range is described in AC/DC characteristics
Output valid
from clock
Bus free time
Input filter spike
suppression
(SDA and SCL)
Min
Max
Units
Conditions
100 kHz mode
250
—
ns
400 kHz mode
100
—
ns
1.7 MHz mode
10
—
ns
3.4 MHz mode
10
—
ns
100 kHz mode
—
3450
ns
400 kHz mode
—
900
ns
1.7 MHz mode
—
150
ns
Cb = 100 pF,
Note 1, Note 7
—
310
ns
Cb = 400 pF,
Note 1, Note 5
3.4 MHz mode
—
150
ns
Cb = 100 pF, Note 1
100 kHz mode
4700
—
ns
Time the bus must be free
before a new transmission
can start
400 kHz mode
1300
—
ns
1.7 MHz mode
N.A.
—
ns
3.4 MHz mode
N.A.
—
ns
100 kHz mode
—
50
ns
400 kHz mode
—
50
ns
Note 2
Note 1
Philips Spec states N.A.
1.7 MHz mode
—
10
ns
Spike suppression
3.4 MHz mode
—
10
ns
Spike suppression
As a transmitter, the device must provide this internal minimum delay time to bridge the undefined region
(minimum 300 ns) of the falling edge of SCL to avoid unintended generation of START or STOP conditions.
A fast-mode (400 kHz) I2C-bus device can be used in a standard-mode (100 kHz) I2C-bus system, but the
requirement tSU;DAT ≥ 250 ns must then be met. This will automatically be the case if the device does not
stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal,
it must output the next data bit to the SDA line
TR max.+tSU;DAT = 1000 + 250 = 1250 ns (according to the standard-mode I2C bus specification) before
the SCL line is released.
The MCP44X1/MCP44X2 device must provide a data hold time to bridge the undefined part between VIH
and VIL of the falling edge of the SCL signal. This specification is not a part of the I2C specification, but
must be tested in order to ensure that the output data will meet the setup and hold specifications for the
receiving device.
Use Cb in pF for the calculations.
Not Tested.
A Master Transmitter must provide a delay to ensure that difference between SDA and SCL fall times do
not unintentionally create a Start or Stop condition.
Ensured by the TAA 3.4 MHz specification test.
DS22265A-page 16
© 2010 Microchip Technology Inc.
MCP444X/446X
TEMPERATURE CHARACTERISTICS
Electrical Specifications: Unless otherwise indicated, VDD = +2.7V to +5.5V, VSS = GND.
Parameters
Sym
Min
Typ
Max
Units
Specified Temperature Range
TA
-40
—
+125
°C
Operating Temperature Range
TA
-40
—
+125
°C
Storage Temperature Range
TA
-65
—
+150
°C
Thermal Resistance, 14L-TSSOP
θJA
—
100
—
°C/W
Thermal Resistance, 20L-QFN
θJA
—
43
—
°C/W
Thermal Resistance, 20L-TSSOP
θJA
—
90
—
°C/W
Conditions
Temperature Ranges
Thermal Package Resistances
© 2010 Microchip Technology Inc.
DS22265A-page 17
MCP444X/446X
NOTES:
DS22265A-page 18
© 2010 Microchip Technology Inc.
MCP444X/446X
2.0
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:
250
550
500
450
400
350
300
250
200
150
100
50
0
200
1.7MHz, 5.5V
1.7MHz, 4.5V
400kHz, 5.5V
100kHz, 5.5V
IHVC
150
100
50
400kHz, 2.7V
IHVC (µA)
3.4MHz, 4.5V
RHVC
100kHz, 2.7V
0
-40
0
40
80
Temperature (°C)
120
FIGURE 2-1:
Device Current (IDD) vs. I2C
Frequency (fSCL) and Ambient Temperature
(VDD = 2.7V and 5.5V).
2
3
4
5
6
7
VHVC (V)
8
9
10
FIGURE 2-4:
HVC/A0 Pull-up/Pull-down
Resistance (RHVC) and Current (IHVC) vs. HVC/
A0 Input Voltage (VHVC) (VDD = 5.5V).
3.0
12.0
2.5
HVC/A0 Threshold (V)
Standby Current (ISHDN) (µA)
1000
800
600
400
200
0
-200
-400
-600
-800
-1000
3.4MHz, 5.5V
RHVC (kOhms)
IDD (µA)
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
5.5V
2.0
1.5
2.7V
1.0
0.5
0.0
10.0
5.5V Entry
8.0
6.0
2.7V Entry
5.5V Exit
2.7V Exit
4.0
2.0
0.0
-40
0
40
80
Ambient Temperature (°C)
120
FIGURE 2-2:
Device Current (ISHDN) and
VDD. (HVC/A0 = VDD) vs. Ambient Temperature.
-40
0
40
80
Ambient Temperature (°C)
120
FIGURE 2-5:
HVC/A0 High Input Entry/
Exit Threshold vs. Ambient Temperature and
VDD.
EE Write Current (IWRITE) (µA)
500
400
5.5V
300
200
2.7V
100
0
-40
0
40
80
Ambient Temperature (°C)
120
FIGURE 2-3:
Write Current (IWRITE) vs.
Ambient Temperature and VDD.
© 2010 Microchip Technology Inc.
DS22265A-page 19
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
0.3
0.2
0.1
80
0
60
-0.1
125°C
20
0
-0.2
RW
-40°C 25°C
85°C
260
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
DNL
180
0
140
RW
100
-0.1
125°C
60
-40°C
25°C
85°C
20
-0.2
-0.3
0
32
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-7:
5 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
DS22265A-page 20
-0.25
40
85°C 25°C
DNL
-40°C
-0.75
RW
-1.25
32
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-8:
5 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
-40C Rw
-40C INL
-40C DNL
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
6
INL
220
0.1
0.75
60
260
0.2
1.25
0.25
300
0.3
INL
220
125C Rw
125C INL
125C DNL
80
0
Error (LSb)
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
85C Rw
85C INL
85C DNL
20
FIGURE 2-6:
5 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
300
25C Rw
25C INL
25C DNL
INL
125°C
-0.3
64 96 128 160 192 224 256
Wiper Setting (decimal)
32
-40C Rw
-40C INL
-40C DNL
100
INL
DNL
40
120
Error (LSb)
125C Rw
125C INL
125C DNL
4
180
2
140
RW
Error (LSb)
85C Rw
85C INL
85C DNL
Wiper Resistance (RW)
(ohms)
100
25C Rw
25C INL
25C DNL
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
Error (LSb)
Wiper Resistance (RW)
(ohms)
120
100
0
-40°C
60
125°C
20
0
32
85°C
25°C
DNL
-2
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-9:
5 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
© 2010 Microchip Technology Inc.
MCP444X/446X
5300
6000
5250
5000
Resistance ()
Nominal Resistance (RAB)
(Ohms)
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
2.7V
5200
5150
5100
4000
3000
2000
-40C
+25C
+85C
+125C
1000
5.5V
5050
0
-40
0
40
80
Ambient Temperature (°C)
120
FIGURE 2-10:
5 kΩ – Nominal Resistance
(RAB) (Ω) vs. Ambient Temperature and VDD.
0
32
64
96
128
160
Wiper Code
192
224
256
FIGURE 2-11:
5 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 5.5V, IW = 190 µA).
6000
Resistance ()
5000
4000
3000
2000
-40C
+25C
+85C
+125C
1000
0
0
32
64
96
128
160
Wiper Code
192
224
256
FIGURE 2-12:
5 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 3.0V, IW = 190 µA).
© 2010 Microchip Technology Inc.
DS22265A-page 21
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
2.50%
CH0
CH2
52
50
PPM / °C
1.50%
Error %
54
-40C
+25C
+85C
+125C
0.50%
-0.50%
CH1
CH3
48
46
44
-1.50%
42
40
-2.50%
0
32
64
96
128
160
192
224
0
256
32
64
Wiper Code
FIGURE 2-13:
5 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 5.5V, IW = 190 µA).
2.50%
224
256
100
CH0
CH2
95
90
PPM / °C
Error %
192
FIGURE 2-15:
5 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 5.5V, IW = 190 µA).
-40C
+25C
+85C
+125C
1.50%
96 128 160
Wiper Code
0.50%
-0.50%
CH1
CH3
85
80
75
70
-1.50%
65
60
-2.50%
0
32
64
96
128
160
192
224
256
Wiper Code
FIGURE 2-14:
5 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 3.0V, IW = 190 µA).
DS22265A-page 22
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-16:
5 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 3.0V, IW = 190 µA).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
FIGURE 2-17:
5 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-20:
5 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-18:
5 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
FIGURE 2-21:
5 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
FIGURE 2-19:
5 kΩ – Power-Up Wiper
Response Time (20 ms/Div).
© 2010 Microchip Technology Inc.
DS22265A-page 23
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
125C Rw
125C INL
125C DNL
INL
DNL
0.3
0.2
0.1
80
0
60
-0.1
40
25°C -40°C
125°C 85°C
120
100
-0.2
RW
20
0
40
220
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
INL
DNL
0.1
180
0
140
100
RW
60
-40°C
25°C
125°C 85°C
20
0
32
300
0.3
0.2
-0.1
-0.2
-0.3
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-23:
10 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
DS22265A-page 24
32
85°C 25°C
RW
-40°C
DNL
-0.5
-1
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-24:
10 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
Wiper Resistance (RW)
(ohms)
260
25C Rw
25C INL
25C DNL
1
60
0
Error (LSb)
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
125C Rw
125C INL
125C DNL
80
20
FIGURE 2-22:
10 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
85C Rw
85C INL
85C DNL
0.5
125°C
-0.3
25C Rw
25C INL
25C DNL
INL
0 25 50 75 100 125 150 175 200 225 250
Wiper Setting (decimal)
300
-40C Rw
-40C INL
-40C DNL
Error (LSb)
85C Rw
85C INL
85C DNL
-40C Rw
-40C INL
-40C DNL
260
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
4
3
INL
220
2
180
1
140
0
100
-40°C
60
DNL
RW
Error (LSb)
100
25C Rw
25C INL
25C DNL
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
Error (LSb)
Wiper Resistance (RW)
(ohms)
120
-1
125°C 85°C 25°C
20
-2
0
25 50 75 100 125 150 175 200 225 250
Wiper Setting (decimal)
FIGURE 2-25:
10 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
© 2010 Microchip Technology Inc.
MCP444X/446X
10250
12000
10200
10000
Resistance ()
Nominal Resistance (RAB)
(Ohms)
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
10150
2.7V
10100
5.5V
10050
8000
6000
4000
-40C
+25C
+85C
+125C
2000
10000
-40
0
40
80
Ambient Temperature (°C)
0
120
FIGURE 2-26:
10 kΩ – Nominal Resistance
(RAB) (Ω) vs. Ambient Temperature and VDD.
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-27:
10 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 5.5V, IW = 150 µA).
12000
Resistance ()
10000
8000
6000
4000
-40C
+25C
+85C
+125C
2000
0
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-28:
10 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 3.0V, IW = 150 µA).
© 2010 Microchip Technology Inc.
DS22265A-page 25
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
1.50%
-40C
+85C
1.00%
45
40
PPM / °C
0.50%
Error %
50
+25C
+125C
0.00%
-0.50%
35
30
25
20
-1.00%
CH0
CH2
15
10
-1.50%
0
32
64
96
128
160
192
224
0
256
32
64
Wiper Code
FIGURE 2-29:
10 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 5.5V, IW = 150 µA).
1.50%
-40C
+85C
1.00%
96 128 160
Wiper Code
192
224
256
FIGURE 2-31:
10 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 5.5V, IW = 150 µA).
60
+25C
+125C
55
50
PPM / °C
0.50%
Error %
CH1
CH3
0.00%
-0.50%
45
40
35
30
-1.00%
CH0
CH2
25
CH1
CH3
20
-1.50%
0
32
64
96
128
160
192
224
256
Wiper Code
FIGURE 2-30:
10 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 3.0V, IW = 150 µA).
DS22265A-page 26
0
32
64
96 128 160
Wiper Code
192
224
256
FIGURE 2-32:
10 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 3.0V, IW = 150 µA).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
FIGURE 2-33:
10 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-35:
10 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-34:
10 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
FIGURE 2-36:
10 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
© 2010 Microchip Technology Inc.
DS22265A-page 27
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
INL
DNL
0.3
0.2
0.1
80
0
60
-0.1
40
125°C
25°C
85°C
20
0
-40°C
120
100
-0.2
RW
-0.3
64 96 128 160 192 224 256
Wiper Setting (decimal)
32
260
220
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
INL
DNL
180
0
140
RW
100
-40°C
60
125°C 85°C 25°C
20
0
32
-0.1
-0.2
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-38:
50 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
DS22265A-page 28
-0.1
40
85°C 25°C
125°C
32
-40°C
RW
-0.2
-0.3
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-39:
50 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
-40C Rw
-40C INL
-40C DNL
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
INL
125C Rw
125C INL
125C DNL
1
0.75
0.5
DNL
0.25
180
0
140
RW
100
-0.25
-0.5
-40°C
60
125°C
-0.3
0.1
0
220
0.1
0.2
60
260
0.2
0.3
125C Rw
125C INL
125C DNL
DNL
300
0.3
85C Rw
85C INL
85C DNL
80
0
Error (LSb)
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
25C Rw
25C INL
25C DNL
INL
20
FIGURE 2-37:
50 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
300
-40C Rw
-40C INL
-40C DNL
Error (LSb)
125C Rw
125C INL
125C DNL
Error (LSb)
85C Rw
85C INL
85C DNL
Wiper Resistance (RW)
(ohms)
100
25C Rw
25C INL
25C DNL
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
Error (LSb)
Wiper Resistance (RW)
(ohms)
120
85°C 25°C
20
0
32
64
-0.75
-1
96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-40:
50 kΩ Rheo Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
60000
50600
50000
50400
50200
Resistance ()
Nominal Resistance (RAB)
(Ohms)
50800
2.7V
50000
5.5V
49800
49600
40000
30000
20000
-40C
+25C
+85C
+125C
10000
49400
-40
0
40
80
Ambient Temperature (°C)
0
120
FIGURE 2-41:
50 kΩ – Nominal Resistance
(RAB) (Ω) vs. Ambient Temperature and VDD.
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-42:
50 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 5.5V, IW = 90 µA).
60000
Resistance ()
50000
40000
30000
-40C
+25C
+85C
+125C
20000
10000
0
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-43:
50 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 3.0V, IW = 48 µA).
© 2010 Microchip Technology Inc.
DS22265A-page 29
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
7.00%
-40C
+85C
6.00%
+25C
+125C
4.00%
PPM / °C
Error %
5.00%
3.00%
2.00%
1.00%
0.00%
-1.00%
0
32
64
96
128
160
192
224
7
6
5
4
3
2
1
0
-1
-2
-3
CH0
CH2
0
256
32
CH1
CH3
64
Wiper Code
FIGURE 2-44:
50 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 5.5V, IW = 90 µA).
192
224
256
FIGURE 2-46:
50 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 5.5V, IW = 90 µA).
12
4.00%
-40C
+85C
3.00%
+25C
+125C
10
8
PPM / °C
2.00%
Error %
96 128 160
Wiper Code
1.00%
0.00%
6
4
2
CH0
CH2
0
-1.00%
CH1
CH3
-2
-2.00%
0
32
64
96
128
160
192
224
256
Wiper Code
FIGURE 2-45:
50 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 3.0V, IW = 48 µA).
DS22265A-page 30
0
32
64
96 128 160
Wiper Code
192
224
256
FIGURE 2-47:
50 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 3.0V, IW = 48 µA).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
FIGURE 2-48:
50 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-50:
50 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-49:
50 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
FIGURE 2-51:
50 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
© 2010 Microchip Technology Inc.
DS22265A-page 31
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
125C Rw
125C INL
125C DNL
0.2
DNL
0
60
-0.1
40
25°C -40°C
-40C Rw
-40C INL
-40C DNL
100
0.1
INL
80
120
RW
-0.2
64 96 128 160 192 224 256
Wiper Setting (decimal)
32
-40C Rw
-40C INL
-40C DNL
260
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
INL
220
DNL
125C Rw
125C INL
125C DNL
-0.1
40
-40°C
0.1
0.05
180
0
140
RW
60
-40°C
125°C 85°C 25°C
20
0
32
-0.1
-0.15
-0.2
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-53:
100 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
DS22265A-page 32
32
-0.2
-0.3
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-54:
100 kΩ Rheo Mode – RW
(Ω), INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
-40C Rw
-40C INL
-40C DNL
25C Rw
25C INL
25C DNL
85C Rw
85C INL
85C DNL
125C Rw
125C INL
125C DNL
INL
220
-0.05
100
RW
125°C 85°C 25°C
260
0.15
0.1
0
300
0.2
Error (LSb)
Wiper Resistance (RW)
(ohms)
300
0.2
60
0
FIGURE 2-52:
100 kΩ Pot Mode – RW (Ω),
INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 5.5V).
0.3
125C Rw
125C INL
125C DNL
DNL
80
20
Wiper Resistance (Rw)
(ohms)
0
85C Rw
85C INL
85C DNL
INL
125°C 85°C
20
25C Rw
25C INL
25C DNL
Error (LSb)
85C Rw
85C INL
85C DNL
0.6
0.4
0.2
DNL
180
0
140
RW
100
60
-40°C
-0.2
Error (LSb)
100
25C Rw
25C INL
25C DNL
Wiper Resistance (RW)
(ohms)
-40C Rw
-40C INL
-40C DNL
Error (LSb)
Wiper Resistance (RW)
(ohms)
120
-0.4
125°C 85°C 25°C
20
-0.6
0
32
64 96 128 160 192 224 256
Wiper Setting (decimal)
FIGURE 2-55:
100 kΩ Rheo Mode – RW
(Ω), INL (LSb), DNL (LSb) vs. Wiper Setting and
Ambient Temperature (VDD = 3.0V).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
120000
100000
101000
100500
Resistance ()
Nominal Resistance (RAB)
(Ohms)
101500
2.7V
100000
5.5V
99500
80000
60000
-40C
+25C
+85C
+125C
40000
20000
99000
-40
0
40
80
Ambient Temperature (°C)
0
120
FIGURE 2-56:
100 kΩ – Nominal
Resistance (RAB) (Ω) vs. Ambient Temperature
and VDD .
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-57:
100 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 5.5V, IW = 45 µA).
120000
Resistance ()
100000
80000
60000
40000
-40C
+25C
+85C
+125C
20000
0
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-58:
100 kΩ – RWB (Ω) vs. Wiper
Setting and Ambient Temperature
(VDD = 3.0V, IW = 24 µA).
© 2010 Microchip Technology Inc.
DS22265A-page 33
MCP444X/446X
14.00%
13.00%
12.00%
11.00%
10.00%
9.00%
8.00%
7.00%
6.00%
5.00%
4.00%
3.00%
2.00%
1.00%
0.00%
-1.00%
-40C
+85C
16
+25C
+125C
14
12
PPM / °C
Error %
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
10
8
6
4
CH0
CH2
2
0
0
32
64
96
128
160
192
224
0
256
32
64
Wiper Code
FIGURE 2-59:
100 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 5.5V, IW = 45 µA).
7.00%
-40C
+85C
6.00%
2.00%
224
256
16
14
PPM / °C
3.00%
192
18
+25C
+125C
4.00%
96 128 160
Wiper Code
FIGURE 2-61:
100 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 5.5V, IW = 45 µA).
5.00%
Error %
CH1
CH3
12
10
8
6
1.00%
4
0.00%
2
CH0
CH2
CH1
CH3
0
-1.00%
0
32
64
96
128
160
192
224
256
Wiper Code
FIGURE 2-60:
100 kΩ – Worst Case RBW
from Average RBW (RBW0-RBW3) Error (%) vs.
Wiper Setting and Temperature
(VDD = 3.0V, IW = 24 µA).
DS22265A-page 34
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE 2-62:
100 kΩ – RWB PPM/°C vs.
Wiper Setting. (RBW(code=n, 125°C)-RBW(code=n, 40°C) )/RBW(code = 256, 25°C)/165°C * 1,000,000)
(VDD = 3.0V, IW = 24 µA).
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
FIGURE 2-63:
100 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-65:
100 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 2.7V)
(1 µs/Div).
FIGURE 2-64:
100 kΩ – Low-Voltage
Decrement Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
FIGURE 2-66:
100 kΩ – Low-Voltage
Increment Wiper Settling Time (VDD = 5.5V)
(1 µs/Div).
© 2010 Microchip Technology Inc.
DS22265A-page 35
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
4
3.5
5.5V
VOL (mV)
VIH (V)
3
2.5
2
2.7V
1.5
230
210
2.7V
190
170
150
130
5.5V
110
90
70
50
1
-40
0
40
80
120
Temperature (°C)
FIGURE 2-67:
Temperature.
-40
0
40
80
120
Temperature (°C)
VIH (SDA, SCL) vs. VDD and
FIGURE 2-69:
VOL (SDA) vs. VDD and
Temperature (IOL = 3 mA).
2
VIL (V)
5.5V
1.5
2.7V
1
-40
0
40
80
120
Temperature (°C)
FIGURE 2-68:
Temperature.
DS22265A-page 36
VIL (SDA, SCL) vs. VDD and
© 2010 Microchip Technology Inc.
MCP444X/446X
Note: Unless otherwise indicated, TA = +25°C, VDD = 5V, VSS = 0V.
2.1
Test Circuits
4.5
4.0
tWC (ms)
3.5
+5V
2.7V
A
VIN
3.0
2.5
5.5V
2.0
-40
0
40
80
Temperature (°C)
B
Offset
GND
1.5
1.6
+
VOUT
-
2.5V DC
120
FIGURE 2-70:
Nominal EEPROM Write
Cycle Time vs. VDD and Temperature.
W
FIGURE 2-72:
Test.
-3 db Gain vs. Frequency
1.4
VDD (V)
1.2
floating
VA
A
1.0
0.8
0.6
VW
W
0.4
IW
0.2
0.0
-40
0
FIGURE 2-71:
and Temperature.
40
80
Temperature (°C)
120
B
VB
RBW = VW/IW
RW = (VW-VA)/IW
POR/BOR Trip point vs. VDD
© 2010 Microchip Technology Inc.
FIGURE 2-73:
RBW and RW Measurement.
DS22265A-page 37
MCP444X/446X
NOTES:
DS22265A-page 38
© 2010 Microchip Technology Inc.
MCP444X/446X
3.0
PIN DESCRIPTIONS
The descriptions of the pins are listed in Table 3-1.
Additional descriptions of the device pins follows.
TABLE 3-1:
PINOUT DESCRIPTION FOR THE MCP444X/446X
Pin
TSSOP
Symbol
I/O
Buffer
Type
Weak
Pull-up/
down
(Note 1)
QFN
Standard Function
14L
20L
20L
—
1
19
P3A
A
Analog
No
Potentiometer 3 Terminal A
1
2
20
P3W
A
Analog
No
Potentiometer 3 Wiper Terminal
1
P3B
A
Analog
No
Potentiometer 3 Terminal B
I
HV w/ST
“smart”
2
3
3
4
2
HVC/A0
4
5
3
SCL
I
HV w/ST
No
I2C Clock Input
5
6
4
SDA
I
HV w/ST
No
I2C Serial Data I/O. Open Drain output
6
7
5
VSS
—
P
—
Ground
7
8
6
P1B
A
Analog
No
Potentiometer 1 Terminal B
8
9
7
P1W
A
Analog
No
Potentiometer 1 Wiper Terminal
—
10
8
P1A
A
Analog
No
Potentiometer 1 Terminal A
A
Analog
No
Potentiometer 0 Terminal A
High Voltage Command / I2C Address 0
—
11
9
P0A
9
12
10
P0W
A
Analog
No
Potentiometer 0 Wiper Terminal
10
13
11
P0B
A
Analog
No
Potentiometer 0 Terminal B
—
14
12
WP
I
HV w/ST
“smart”
13
RESET
I
HV w/ST
Yes
I
HV w/ST
“smart”
—
15
Hardware EEPROM Write Protect
Hardware Reset Pin
11
16
14
A1
12
17
15
VDD
—
P
—
Positive Power Supply Input
13
18
16
P2B
A
Analog
No
Potentiometer 2 Terminal B
A
Analog
No
Potentiometer 2 Wiper Terminal
I2C Address 1
14
19
17
P2W
—
20
18
P2A
A
Analog
No
Potentiometer 2 Terminal A
—
—
21
EP
—
—
—
Exposed Pad. (Note 2)
Legend:
Note 1:
2:
HV w/ST = High Voltage tolerant input (with Schmidtt trigger input)
A = Analog pins (Potentiometer terminals)
I = digital input (high Z)
O = digital output
I/O = Input / Output
P = Power
The pin’s “smart” pull-up shuts off while the pin is forced low. This is done to reduce the standby and
shut-down current.
The QFN package has a contact on the bottom of the package. This contact is conductively connected to
the die substrate, and therefore should be unconnected or connected to the same ground as the device’s
VSS pin.
© 2010 Microchip Technology Inc.
DS22265A-page 39
MCP444X/446X
3.1
High Voltage Command /
Address 0 (HVC/A0)
The HVC/A0 pin is the Address 0 input for the I2C
interface as well as the High Voltage Command pin. At
the device’s POR/BOR the value of the A0 address bit
is latched. This input along with the A1 pin completes
the device address. This allows up to 4 MCP44XX
devices to be on a single I2C bus.
3.7
Potentiometer Terminal A
The terminal A pin is available on the MCP44X1
devices, and is connected to the internal
potentiometer’s terminal A.
The potentiometer’s terminal A is the fixed connection
to the Full Scale wiper value of the digital
potentiometer. This corresponds to a wiper value of
0x100 for 8-bit devices or 0x80 for 7-bit devices.
During normal operation, the voltage on this pin
determines whether the I2C command is a normal
command or a High Voltage command (when HVC/A0
= VIHH).
The terminal A pin does not have a polarity relative to
the terminal W or B pins. The terminal A pin can
support both positive and negative current. The voltage
on terminal A must be between VSS and VDD.
3.2
The terminal A pin is not available on the MCP44X2
devices, and the internally terminal A signal is floating.
Serial Clock (SCL)
The SCL pin is the serial interfaces Serial Clock pin.
This pin is connected to the Host Controllers SCL pin.
The MCP44XX is a slave device, so its SCL pin accepts
only external clock signals.
3.3
Serial Data (SDA)
The SDA pin is the serial interfaces Serial Data pin.
This pin is connected to the Host Controllers SDA pin.
The SDA pin is an open-drain N-channel driver.
3.4
Ground (VSS)
The VSS pin is the device ground reference.
3.5
Potentiometer Terminal B
The terminal B pin is connected to the internal
potentiometer’s terminal B.
The potentiometer’s terminal B is the fixed connection
to the Zero Scale wiper value of the digital
potentiometer. This corresponds to a wiper value of
0x00 for both 7-bit and 8-bit devices.
The terminal B pin does not have a polarity relative to
the terminal W or A pins. The terminal B pin can
support both positive and negative current. The voltage
on terminal B must be between VSS and VDD.
MCP44XX devices have four terminal B pins, one for
each resistor network.
MCP44X1 devices have four terminal A pins, one for
each resistor network. Terminal A is not available on
the MCP44X2 devices.
3.8
Write Protect (WP)
The WP pin is used to force the nonvolatile memory to
be write protected.
3.9
Reset (RESET)
The RESET pin is used to force the device into the
POR/BOR state.
3.10
Address 1 (A1)
The A1 pin is the I2C interface’s Address 1 pin. Along
with the A0 pins, up to 4 MCP44XX devices can be on
a single I2C bus.
3.11
Positive Power Supply Input (VDD)
The VDD pin is the device’s positive power supply input.
The input power supply is relative to VSS.
While the device VDD < Vmin (2.7V), the electrical
performance of the device may not meet the data sheet
specifications.
3.12
No Connect (NC)
These pins should be either connected to VDD or VSS.
3.6
Potentiometer Wiper (W) Terminal
The terminal W pin is connected to the internal
potentiometer’s terminal W (the wiper). The wiper
terminal is the adjustable terminal of the digital
potentiometer. The terminal W pin does not have a
polarity relative to terminals A or B pins. The terminal
W pin can support both positive and negative current.
The voltage on terminal W must be between VSS and
VDD.
3.13
Exposed Pad (EP)
This pad is conductively connected to the device's
substrate. This pad should be tied to the same potential
as the VSS pin (or left unconnected). This pad could be
used to assist as a heat sink for the device when
connected to a PCB heat sink.
MCP44XX devices have four terminal W pins, one for
each resistor network.
DS22265A-page 40
© 2010 Microchip Technology Inc.
MCP444X/446X
4.0
FUNCTIONAL OVERVIEW
This Data Sheet covers a family of four nonvolatile Digital Potentiometer and Rheostat devices that will be
referred to as MCP44XX. The MCP44X1 devices are
the Potentiometer configuration, while the MCP44X2
devices are the Rheostat configuration.
As the Device Block Diagram shows, there are four
main functional blocks. These are:
•
•
•
•
POR/BOR and RESET Operation
Memory Map
Resistor Network
Serial Interface (I2C)
The POR/BOR operation and the Memory Map are
discussed in this section and the Resistor Network and
I2C operation are described in their own sections. The
Device Commands commands are discussed in
Section 7.0.
4.1
POR/BOR and RESET Operation
The Power-on Reset is the case where the device is
having power applied to it from VSS. The Brown-out
Reset occurs when a device had power applied to it,
and that power (voltage) drops below the specified
range.
The devices RAM retention voltage (VRAM) is lower
than the POR/BOR voltage trip point (VPOR/VBOR). The
maximum VPOR/VBOR voltage is less then 1.8V.
When VPOR/VBOR < VDD < 2.7V, the electrical
performance may not meet the data sheet
specifications. In this region, the device is capable of
reading and writing to its EEPROM and incrementing,
decrementing, reading and writing to its volatile
memory if the proper serial command is executed.
When VDD < VPOR/VBOR or the RESET pin is Low, the
pin weak pull-ups are enabled.
4.1.1
POWER-ON RESET
When the device powers up, the device VDD will cross
the VPOR/VBOR voltage. Once the VDD voltage crosses
the VPOR/VBOR voltage, the following happens:
• The volatile wiper register is loaded with value in
the corresponding nonvolatile wiper register
• The TCON registers are loaded with their default
value
• The device is capable of digital operation
© 2010 Microchip Technology Inc.
4.1.2
BROWN-OUT RESET
When the device powers down, the device VDD will
cross the VPOR/VBOR voltage.
Once the VDD voltage decreases below the VPOR/VBOR
voltage, the following happens:
• Serial Interface is disabled
• EEPROM Writes are disabled
If the VDD voltage decreases below the VRAM voltage,
the following happens:
• Volatile wiper registers may become corrupted
• TCON registers may become corrupted
As the voltage recovers above the VPOR/VBOR voltage,
see Section 4.1.1 “Power-on Reset”.
Serial commands not completed due to a brown-out
condition may cause the memory location (volatile and
nonvolatile) to become corrupted.
4.1.3
RESET PIN
The RESET pin can be used to force the device into
the POR/BOR state of the device. When the RESET
pin is forced Low, the device is forced into the reset
state. This means that the TCON and STATUS
registers are forced to their default values and the
volatile wiper registers are loaded with the value in the
corresponding Nonvolatile wiper register. Also the I2C
interface is disabled. Any nonvolatile write cycle is not
interrupted, and allowed to complete.
This feature allows a hardware method for all registers
to be updated at the same time.
4.1.4
INTERACTION OF RESET PIN AND
BOR/POR CIRCUITRY
Figure 4-1 shows how the RESET pin signal and the
POR/BOR signal interact to control the hardware reset
state of the device.
RESET (from pin)
Device reset
POR/BOR signal
FIGURE 4-1:
POR/BOR Signal and
RESET Pin Interaction.
DS22265A-page 41
MCP444X/446X
4.2
Memory Map
The device memory has 16 locations that are 9-bit wide
(16x9 bits). This memory space contains both volatile
and nonvolatile locations (see Table 4-1).
TABLE 4-1:
Address
MEMORY MAP AND THE SUPPORTED COMMANDS
Function
Memory
Type
Allowed Commands
Disallowed Commands (2)
Factory
Initialization
00h
Volatile Wiper 0
RAM
Read, Write,
Increment, Decrement
—
—
01h
Volatile Wiper 1
RAM
Read, Write,
Increment, Decrement
—
—
02h
Nonvolatile Wiper 0
EEPROM
Read, Write (1)
Increment, Decrement
03h
Nonvolatile Wiper 1
EEPROM
Read, Write (1)
Increment, Decrement
8-bit
80h
7-bit
40h
8-bit
80h
7-bit
40h
04h
Volatile
TCON0 Register
RAM
Read, Write
Increment, Decrement
—
05h
Status Register
RAM
Read
Write, Increment, Decrement
—
06h
Volatile Wiper 2
RAM
Read, Write,
Increment, Decrement
—
—
07h
Volatile Wiper 3
RAM
Read, Write,
Increment, Decrement
—
—
08h
Nonvolatile Wiper 2
EEPROM
Read, Write (1)
Increment, Decrement
09h
Nonvolatile Wiper 3
0Ah
Volatile
TCON1 Register
0Bh
Data EEPROM
EEPROM
Read, Write (1)
Increment, Decrement
8-bit
80h
7-bit
40h
8-bit
80h
7-bit
40h
RAM
Read, Write
Increment, Decrement
—
EEPROM
Read, Write (1)
Increment, Decrement
000h
(1)
0Ch
Data EEPROM
EEPROM
Read, Write
Increment, Decrement
000h
0Dh
Data EEPROM
EEPROM
Read, Write (1)
Increment, Decrement
000h
(1)
Increment, Decrement
000h
Increment, Decrement
000h
0Eh
Data EEPROM
EEPROM
Read, Write
0Fh
Data EEPROM
EEPROM
Read, Write (1)
Note 1:
2:
When an EEPROM write is active, these are invalid commands and will generate an error condition. The
user should use a read of the Status register to determine when the write cycle has completed. To exit the
error condition, the user must take the HVC pin to the VIH level and then back to the active state (VIL or
VIHH).
This command on this address will generate an error condition. To exit the error condition, the user must
take the HVC pin to the VIH level and then back to the active state (VIL or VIHH).
DS22265A-page 42
© 2010 Microchip Technology Inc.
MCP444X/446X
4.2.1
4.2.1.4
NONVOLATILE MEMORY
(EEPROM)
This memory can be grouped into two uses of
nonvolatile memory. These are:
• General Purpose Registers
• Nonvolatile Wiper Registers
The nonvolatile wipers start functioning below the
devices VPOR/VBOR trip point.
4.2.1.1
General Purpose Registers
These locations allow the user to store up to 5 (9-bit)
locations worth of information.
4.2.1.2
Nonvolatile Wiper Registers
These locations contain the wiper values that are
loaded into the corresponding volatile wiper register
whenever the device has a POR/BOR event. There are
four registers, one for each resistor network.
The nonvolatile wiper register enables stand-alone
operation of the device (without Microcontroller control)
after being programmed to the desired value.
4.2.1.3
Factory Initialization of Nonvolatile
Memory (EEPROM)
The Nonvolatile Wiper values will be initialized to
mid-scale value. This is shown in Table 4-2.
The General purpose EEPROM memory will be
programmed to a default value of 0x000.
It is good practice in the manufacturing flow to
configure the device to your desired settings.
-502
5.0 kΩ
Mid scale
80h
40h
Disabled
-103
10.0 kΩ
Mid scale
80h
40h
Disabled
-503
50.0 kΩ
Mid scale
80h
40h
Disabled
-104
100.0 kΩ Mid scale
80h
40h
Disabled
Resistance
Code
Default POR
Wiper Setting
Wiper
Code
WiperLockTM
Technology and
Write Protect Setting
DEFAULT FACTORY
SETTINGS SELECTION
Typical
RAB Value
TABLE 4-2:
© 2010 Microchip Technology Inc.
8-bit 7-bit
Special Features
There are 5 nonvolatile bits that are not directly
mapped into the address space. These bits control the
following functions:
•
•
•
•
•
EEPROM Write Protect
WiperLock Technology for Nonvolatile Wiper 0
WiperLock Technology for Nonvolatile Wiper 1
WiperLock Technology for Nonvolatile Wiper 2
WiperLock Technology for Nonvolatile Wiper 3
The operation of WiperLock Technology is discussed in
Section 5.3. The state of the WL0, WL1, WL2, WL3,
and WP bits is reflected in the STATUS register (see
Register 4-1).
EEPROM Write Protect
All internal EEPROM memory can be Write Protected.
When EEPROM memory is Write Protected, Write
commands to the internal EEPROM are prevented.
Write Protect (WP) can be enabled/disabled by two
methods. These are:
• External WP Hardware pin (MCP44X1 devices
only)
• Nonvolatile configuration bit (WP)
High Voltage commands are required to enable and
disable the nonvolatile WP bit. These commands are
shown in Section 7.8 “Modify Write Protect or
WiperLock Technology (High Voltage)”.
To write to EEPROM, both the external WP pin and the
internal WP EEPROM bit must be disabled. Write
Protect does not block commands to the volatile
registers.
4.2.2
VOLATILE MEMORY (RAM)
There are seven Volatile Memory locations. These are:
•
•
•
•
•
•
•
Volatile Wiper 0
Volatile Wiper 1
Volatile Wiper 2
Volatile Wiper 3
Status Register
Terminal Control (TCON0) Register 0
Terminal Control (TCON)1 Register 1
The volatile memory starts functioning at the RAM
retention voltage (VRAM).
DS22265A-page 43
MCP444X/446X
4.2.2.1
Status (STATUS) Register
This register contains 7 status bits. These bits show the
state of the WiperLock bits, the Write Protect bit, and if
an EEPROM write cycle is active. The STATUS register
can be accessed via the READ commands. Register 41 describes each STATUS register bit.
The STATUS register is placed at Address 05h.
REGISTER 4-1:
R-1
STATUS REGISTER
R-1
D8:D7
R-1
WL3
R-1
(1)
WL2
R-0
(1)
EEWA
R-x
WL1
R-x
(1)
WL0
(1)
R-1
R-x
—
WP (1)
bit 7
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
-n = Value at POR
‘1’ = Bit is set
‘0’ = Bit is cleared
x = Bit is unknown
bit 8-7
D8:D7: Reserved. Forced to “1”
bit 6
WL3: WiperLock Status bit for Resistor Network 3 (Refer to Section 5.3 “WiperLock Technology” for
further information)
The WiperLock Technology bit (WL3) prevents the Volatile and Nonvolatile Wiper 3 addresses and the
TCON1 register bits R3HW, R3A, R3W, and R3B from being written to. High Voltage commands are
required to enable and disable WiperLock Technology.
1 = Wiper and TCON1 register bits R3HW, R3A, R3W, and R3B of Resistor Network 3 (Pot 3) are
“Locked” (Write Protected)
0 = Wiper and TCON1 of Resistor Network 3 (Pot 3) can be modified
Note:
bit 5
WL2: WiperLock Status bit for Resistor Network 2 (Refer to Section 5.3 “WiperLock Technology” for
further information)
The WiperLock Technology bit (WL2) prevents the Volatile and Nonvolatile Wiper 2 addresses and the
TCON1 register bits R2HW, R2A, R2W, and R2B from being written to. High Voltage commands are
required to enable and disable WiperLock Technology.
1 = Wiper and TCON1 register bits R2HW, R2A, R2W, and R2B of Resistor Network 2 (Pot 2) are
“Locked” (Write Protected)
0 = Wiper and TCON1 of Resistor Network 2 (Pot 2) can be modified
Note:
bit 4
Note 1:
The WL3 bit always reflects the result of the last programming cycle to the nonvolatile WL3
bit. After a POR/BOR or RESET pin event, the WL3 bit is loaded with the nonvolatile WL3 bit
value.
The WL0 bit always reflects the result of the last programming cycle to the nonvolatile WL0
bit. After a POR/BOR or RESET pin event, the WL0 bit is loaded with the nonvolatile WL0 bit
value.
EEWA: EEPROM Write Active Status bit
This bit indicates if the EEPROM Write Cycle is occurring.
1 = An EEPROM Write cycle is currently occurring. Only serial commands to the Volatile memory
locations are allowed (addresses 00h, 01h, 04h, and 05h)
0 = An EEPROM Write cycle is NOT currently occurring
Requires a High Voltage command to modify the state of this bit (for Nonvolatile devices only). This bit is
not directly written, but reflects the system state (for this feature).
DS22265A-page 44
© 2010 Microchip Technology Inc.
MCP444X/446X
REGISTER 4-1:
bit 3
WL1: WiperLock Status bit for Resistor Network 1 (Refer to Section 5.3 “WiperLock Technology” for
further information)
The WiperLock Technology bit (WL1) prevents the Volatile and Nonvolatile Wiper 1 addresses and the
TCON0 register bits R1HW, R1A, R1W, and R1B from being written to. High Voltage commands are
required to enable and disable WiperLock Technology.
1 = Wiper and TCON0 register bits R1HW, R1A, R1W, and R1B of Resistor Network 1 (Pot 1) are
“Locked” (Write Protected)
0 = Wiper and TCON0 of Resistor Network 1 (Pot 1) can be modified
Note:
bit 2
STATUS REGISTER (CONTINUED)
The WL1 bit always reflects the result of the last programming cycle to the nonvolatile WL1
bit. After a POR/BOR or RESET pin event, the WL1 bit is loaded with the nonvolatile WL1 bit
value.
WL0: WiperLock Status bit for Resistor Network 0 (Refer to Section 5.3 “WiperLock Technology” for
further information)
The WiperLock Technology bit (WL0) prevents the Volatile and Nonvolatile Wiper 0 addresses and the
TCON0 register bits R0HW, R0A, R0W, and R0B from being written to. High Voltage commands are
required to enable and disable WiperLock Technology.
1 = Wiper and TCON0 register bits R0HW, R0A, R0W, and R0B of Resistor Network 0 (Pot 0) are
“Locked” (Write Protected)
0 = Wiper and TCON0 of Resistor Network 0 (Pot 0) can be modified
Note:
The WL0 bit always reflects the result of the last programming cycle to the nonvolatile WL0
bit. After a POR/BOR or RESET pin event, the WL0 bit is loaded with the nonvolatile WL0 bit
value.
bit 1
Reserved: Forced to “1”
bit 0
WP: EEPROM Write Protect Status bit (Refer to Section “EEPROM Write Protect” for further
information)
This bit indicates the status of the write protection on the EEPROM memory. When Write Protect is
enabled, writes to all nonvolatile memory are prevented. This includes the General Purpose EEPROM
memory, and the nonvolatile Wiper registers. Write Protect does not block modification of the volatile
wiper register values or the volatile TCON0 and TCON1 register values (via Increment, Decrement, or
Write commands).
This status bit is an OR of the devices Write Protect pin (WP) and the internal nonvolatile WP bit. High
Voltage commands are required to enable and disable the internal WP EEPROM bit.
1 = EEPROM memory is Write Protected
0 = EEPROM memory can be written
Note 1:
Requires a High Voltage command to modify the state of this bit (for Nonvolatile devices only). This bit is
not directly written, but reflects the system state (for this feature).
© 2010 Microchip Technology Inc.
DS22265A-page 45
MCP444X/446X
4.2.2.2
Terminal Control (TCON) Registers
There are two Terminal Control (TCON) Registers.
These are called TCON0 and TCON1. Each register
contains 8 control bits, four bits for each Wiper.
Register 4-2 describes each bit of the TCON0 register,
while Register 4-3 describes each bit of the TCON1
register.
The state of each resistor network terminal connection
is individually controlled. That is, each terminal
connection (A, B and W) can be individually connected/
disconnected from the resistor network. This allows the
system to minimize the currents through the digital
potentiometer.
DS22265A-page 46
The value that is written to the specified TCON register
will appear on the appropriate resistor network
terminals when the serial command has completed.
When the WL1 bit is enabled, writes to the TCON0
register bits R1HW, R1A, R1W, and R1B are inhibited.
When the WL0 bit is enabled, writes to the TCON0
register bits R0HW, R0A, R0W, and R0B are inhibited.
When the WL3 bit is enabled, writes to the TCON1
register bits R3HW, R3A, R3W, and R3B are inhibited.
When the WL2 bit is enabled, writes to the TCON1
register bits R2HW, R2A, R2W, and R2B are inhibited.
On a POR/BOR these registers are loaded with
1FFh (9-bit), for all terminals connected. The Host
Controller needs to detect the POR/BOR event and
then update the Volatile TCON register values.
© 2010 Microchip Technology Inc.
MCP444X/446X
REGISTER 4-2:
TCON0 BITS (1)
R-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
D8
R1HW
R1A
R1W
R1B
R0HW
R0A
R0W
R0B
bit 8
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
-n = Value at POR
‘1’ = Bit is set
‘0’ = Bit is cleared
x = Bit is unknown
bit 8
D8: Reserved. Forced to “1”
bit 7
R1HW: Resistor 1 Hardware Configuration Control bit
This bit forces Resistor 1 into the “shutdown” configuration of the Hardware pin
1 = Resistor 1 is NOT forced to the hardware pin “shutdown” configuration
0 = Resistor 1 is forced to the hardware pin “shutdown” configuration
bit 6
R1A: Resistor 1 Terminal A (P1A pin) Connect Control bit
This bit connects/disconnects the Resistor 1 Terminal A to the Resistor 1 Network
1 = P1A pin is connected to the Resistor 1 Network
0 = P1A pin is disconnected from the Resistor 1 Network
bit 5
R1W: Resistor 1 Wiper (P1W pin) Connect Control bit
This bit connects/disconnects the Resistor 1 Wiper to the Resistor 1 Network
1 = P1W pin is connected to the Resistor 1 Network
0 = P1W pin is disconnected from the Resistor 1 Network
bit 4
R1B: Resistor 1 Terminal B (P1B pin) Connect Control bit
This bit connects/disconnects the Resistor 1 Terminal B to the Resistor 1 Network
1 = P1B pin is connected to the Resistor 1 Network
0 = P1B pin is disconnected from the Resistor 1 Network
bit 3
R0HW: Resistor 0 Hardware Configuration Control bit
This bit forces Resistor 0 into the “shutdown” configuration of the Hardware pin
1 = Resistor 0 is NOT forced to the hardware pin “shutdown” configuration
0 = Resistor 0 is forced to the hardware pin “shutdown” configuration
bit 2
R0A: Resistor 0 Terminal A (P0A pin) Connect Control bit
This bit connects/disconnects the Resistor 0 Terminal A to the Resistor 0 Network
1 = P0A pin is connected to the Resistor 0 Network
0 = P0A pin is disconnected from the Resistor 0 Network
bit 1
R0W: Resistor 0 Wiper (P0W pin) Connect Control bit
This bit connects/disconnects the Resistor 0 Wiper to the Resistor 0 Network
1 = P0W pin is connected to the Resistor 0 Network
0 = P0W pin is disconnected from the Resistor 0 Network
bit 0
R0B: Resistor 0 Terminal B (P0B pin) Connect Control bit
This bit connects/disconnects the Resistor 0 Terminal B to the Resistor 0 Network
1 = P0B pin is connected to the Resistor 0 Network
0 = P0B pin is disconnected from the Resistor 0 Network
Note 1:
These bits do not affect the wiper register values.
© 2010 Microchip Technology Inc.
DS22265A-page 47
MCP444X/446X
REGISTER 4-3:
TCON1 BITS (1)
R-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
D8
R3HW
R3A
R3W
R3B
R2HW
R2A
R2W
R2B
bit 8
bit 0
Legend:
R = Readable bit
W = Writable bit
U = Unimplemented bit, read as ‘0’
-n = Value at POR
‘1’ = Bit is set
‘0’ = Bit is cleared
x = Bit is unknown
bit 8
D8: Reserved. Forced to “1”
bit 7
R3HW: Resistor 3 Hardware Configuration Control bit
This bit forces Resistor 3 into the “shutdown” configuration of the Hardware pin
1 = Resistor 3 is NOT forced to the hardware pin “shutdown” configuration
0 = Resistor 3 is forced to the hardware pin “shutdown” configuration
bit 6
R3A: Resistor 3 Terminal A (P3A pin) Connect Control bit
This bit connects/disconnects the Resistor 3 Terminal A to the Resistor 3 Network
1 = P3A pin is connected to the Resistor 3 Network
0 = P3A pin is disconnected from the Resistor 3 Network
bit 5
R3W: Resistor 3 Wiper (P3W pin) Connect Control bit
This bit connects/disconnects the Resistor 3 Wiper to the Resistor 3 Network
1 = P3W pin is connected to the Resistor 3 Network
0 = P3W pin is disconnected from the Resistor 3 Network
bit 4
R3B: Resistor 3 Terminal B (P3B pin) Connect Control bit
This bit connects/disconnects the Resistor 3 Terminal B to the Resistor 3 Network
1 = P3B pin is connected to the Resistor 3 Network
0 = P3B pin is disconnected from the Resistor 3 Network
bit 3
R2HW: Resistor 2 Hardware Configuration Control bit
This bit forces Resistor 2 into the “shutdown” configuration of the Hardware pin
1 = Resistor 2 is NOT forced to the hardware pin “shutdown” configuration
0 = Resistor 2 is forced to the hardware pin “shutdown” configuration
bit 2
R2A: Resistor 2 Terminal A (P0A pin) Connect Control bit
This bit connects/disconnects the Resistor 2 Terminal A to the Resistor 2 Network
1 = P2A pin is connected to the Resistor 2 Network
0 = P2A pin is disconnected from the Resistor 2 Network
bit 1
R2W: Resistor 2 Wiper (P0W pin) Connect Control bit
This bit connects/disconnects the Resistor 2 Wiper to the Resistor 2 Network
1 = P2W pin is connected to the Resistor 2 Network
0 = P2W pin is disconnected from the Resistor 2 Network
bit 0
R2B: Resistor 2 Terminal B (P2B pin) Connect Control bit
This bit connects/disconnects the Resistor 2 Terminal B to the Resistor 2 Network
1 = P2B pin is connected to the Resistor 2 Network
0 = P2B pin is disconnected from the Resistor 2 Network
Note 1:
These bits do not affect the wiper register values.
DS22265A-page 48
© 2010 Microchip Technology Inc.
MCP444X/446X
5.0
RESISTOR NETWORK
5.1
The Resistor Network has either 7-bit or 8-bit
resolution. Each Resistor Network allows zero scale to
full scale connections. Figure 5-1 shows a block
diagram for the resistive network of a device.
The Resistor Network is made up of several parts.
These include:
• Resistor Ladder
• Wiper
• Shutdown (Terminal Connections)
Devices have four resistor networks. These are
referred to as Pot 0, Pot 1 Pot 2, and Pot 3.
A
RW
RS
RW
RS
RW
R
RAB S
8-Bit
N=
257
(1) (100h)
7-Bit
N=
128
(80h)
256
(1) (FFh)
127
(7Fh)
255
(FEh)
126
(7Eh)
(1)
RW
RS
RW
1
(01h)
0
(00h)
0
(00h)
(1)
The resistor ladder is a series of equal value resistors
(RS) with a connection point (tap) between the two
resistors. The total number of resistors in the series
(ladder) determines the RAB resistance (see Figure 51). The end points of the resistor ladder are connected
to analog switches which are connected to the device
Terminal A and Terminal B pins. The RAB (and RS)
resistance has small variations over voltage and
temperature.
For an 8-bit device, there are 256 resistors in a string
between terminal A and terminal B. The wiper can be
set to tap onto any of these 256 resistors, thus
providing 257 possible settings (including terminal A
and terminal B).
For a 7-bit device, there are 128 resistors in a string
between terminal A and terminal B. The wiper can be
set to tap onto any of these 128 resistors, thus
providing 129 possible settings (including terminal A
and terminal B).
Equation 5-1 shows the calculation for the step
resistance.
EQUATION 5-1:
W
1
(1) (01h)
Resistor Ladder Module
RS CALCULATION
RAB
RS = ------------( 256 )
8-bit Device
R AB
R S = -------------( 128 )
7-bit Device
Analog Mux
B
Note 1:
The wiper resistance is dependent on
several factors including, wiper code,
device VDD, Terminal voltages (on A, B,
and W), and temperature.
Also for the same conditions, each tap
selection resistance has a small variation.
This RW variation has greater effects on
some specifications (such as INL) for the
smaller resistance devices (5.0 kΩ)
compared to larger resistance devices
(100.0 kΩ).
FIGURE 5-1:
Resistor Block Diagram.
© 2010 Microchip Technology Inc.
DS22265A-page 49
MCP444X/446X
5.2
Wiper
5.3
Each tap point (between the RS resistors) is a
connection point for an analog switch. The opposite
side of the analog switch is connected to a common
signal which is connected to the Terminal W (Wiper)
pin.
A value in the volatile wiper register selects which
analog switch to close, connecting the W terminal to
the selected node of the resistor ladder.
The wiper can connect directly to Terminal B or to
Terminal A. A zero scale connections, connects the
Terminal W (wiper) to Terminal B (wiper setting of
000h). A full scale connection, connects the Terminal W
(wiper) to Terminal A (wiper setting of 100h or 80h). In
these configurations, the only resistance between the
Terminal W and the other Terminal (A or B) is that of the
analog switches.
A wiper setting value greater than full scale (wiper
setting of 100h for 8-bit device or 80h for 7-bit devices)
will also be a Full Scale setting (Terminal W (wiper)
connected to Terminal A). Table 5-1 illustrates the full
wiper setting map.
Equation 5-2 illustrates the calculation used to
determine the resistance between the wiper and
terminal B.
EQUATION 5-2:
RWB CALCULATION
R AB N
R WB = -------------- + R W
( 256 )
8-bit Device
N = 0 to 256 (decimal)
R WB
R AB N
= -------------- + R W
( 128 )
7-bit Device
N = 0 to 128 (decimal)
TABLE 5-1:
WiperLock Technology
The MCP44XX device’s WiperLock technology allows
application-specific calibration settings to be secured in
the EEPROM without requiring the use of an additional
write-protect pin. There are four WiperLock Technology
configuration bits (WL0, WL1, WL2, and WL3). These
bits prevent the Nonvolatile and Volatile addresses and
bits for the specified resistor network from being written.
The WiperLock technology prevents
commands from doing the following:
the
serial
• Changing a volatile wiper value
• Writing to the specified nonvolatile wiper memory
location
• Changing the related volatile TCON register bits
For either Resistor Network 0, Resistor Network 1,
Resistor Network 2, or Resistor Network 3 (Potx), the
WLx bit controls the following:
• Nonvolatile Wiper Register
• Volatile Wiper Register
• Volatile TCON register bits RxHW, RxA, RxW, and
RxB
High Voltage commands are required to enable and
disable WiperLock. Please refer to the Modify Write
Protect or WiperLock Technology (High Voltage)
command for operation.
5.3.1
POR/BOR OPERATION WHEN
WIPERLOCK TECHNOLOGY
ENABLED
The WiperLock Technology state is not affected by a
POR/BOR event. A POR/BOR event will load the
Volatile Wiper register value with the Nonvolatile Wiper
register value, refer to Section 4.1.
VOLATILE WIPER VALUE VS.
WIPER POSITION MAP
Wiper Setting
Properties
7-bit
8-bit
3FFh – 3FFh – Reserved (Full Scale (W = A)),
081h
101h Increment and Decrement
commands ignored
080h
100h Full Scale (W = A),
Increment commands ignored
07Fh – 0FFh – W = N
041h
081h
040h
080h W = N (Mid Scale)
03Fh – 07Fh – W = N
001h
001h
000h
000h Zero Scale (W = B)
Decrement command ignored
DS22265A-page 50
© 2010 Microchip Technology Inc.
MCP444X/446X
Shutdown
Shutdown is used to minimize the device’s current
consumption. The MCP44XX has one method to
achieve this. This is:
• Terminal Control Register (TCON)
This is different from the MCP42XXX devices in that the
Hardware Shutdown Pin (SHDN) has been replaced by
a RESET pin. The Hardware Shutdown Pin function is
still available via software commands to the TCON
register.
5.4.1
TERMINAL CONTROL REGISTER
(TCON)
The Terminal Control (TCON) register is a volatile
register used to configure the connection of each
resistor network terminal pin (A, B, and W) to the
Resistor Network. These registers are shown in
Register 4-2 and Register 4-3.
The RxHW bit does NOT corrupt the values in the
Volatile Wiper Registers nor the TCON register. When
the Shutdown mode is exited (RxHW bit = “1”):
• The device returns to the Wiper setting specified
by the Volatile Wiper value
• The TCON register bits return to controlling the
terminal connection state
A
Resistor Network
5.4
W
B
FIGURE 5-2:
Resistor Network Shutdown
State (RxHW = ‘0’).
The RxHW bits forces the selected resistor network
into the same state as the MCP42X1’s SHDN pin.
Alternate low power configurations may be achieved
with the RxA, RxW, and RxB bits.
When the RxHW bit is “0”:
• The P0A, P1A, P2A, and P3A terminals are
disconnected
• The P0W, P1W, P2W, and P3W terminals are
simultaneously connect to the P0B, P1B, P2B,
and P3B terminals, respectively (see Figure 5-2)
Note:
When the RxHW bit forces the resistor
network into the hardware SHDN state,
the state of the TCON0 or TCON1
register’s RxA, RxW, and RxB bits is
overridden (ignored). When the state of
the RxHW bit no longer forces the resistor
network into the hardware SHDN state,
the TCON0 or TCON1 register’s RxA,
RxW, and RxB bits return to controlling the
terminal connection state. In other words,
the RxHW bit does not corrupt the state of
the RxA, RxW, and RxB bits.
© 2010 Microchip Technology Inc.
DS22265A-page 51
MCP444X/446X
NOTES:
DS22265A-page 52
© 2010 Microchip Technology Inc.
MCP444X/446X
6.0
SERIAL INTERFACE (I2C)
The MCP44XX devices support the I2C serial protocol.
The MCP44XX I2C’s module operates in Slave mode
(does not generate the serial clock).
Figure 6-1 shows a typical I2C Interface connection. All
I2C interface signals are high-voltage tolerant.
The MCP44XX devices use the two-wire I2C serial
interface. This interface can operate in standard, fast or
High-Speed mode. A device that sends data onto the
bus is defined as transmitter, and a device receiving
data as receiver. The bus has to be controlled by a
master device which generates the serial clock (SCL),
controls the bus access and generates the START and
STOP conditions. The MCP44XX device works as
slave. Both master and slave can operate as
transmitter or receiver, but the master device
determines which mode is activated. Communication is
initiated by the master (microcontroller) which sends
the START bit, followed by the slave address byte. The
first byte transmitted is always the slave address byte,
which contains the device code, the address bits, and
the R/W bit.
Refer to the Phillips I2C document for more details of
the I2C specifications.
Typical I2C Interface Connections
MCP4XXX
6.1
Signal Descriptions
The I2C interface uses up to four pins (signals). These
are:
•
•
•
•
SDA (Serial Data)
SCL (Serial Clock)
A0 (Address 0 bit)
A1 (Address 1 bit)
6.1.1
SERIAL DATA (SDA)
The Serial Data (SDA) signal is the data signal of the
device. The value on this pin is latched on the rising
edge of the SCL signal when the signal is an input.
With the exception of the START and STOP conditions,
the high or low state of the SDA pin can only change
when the clock signal on the SCL pin is low. During the
high period of the clock, the SDA pin’s value (high or
low) must be stable. Changes in the SDA pin’s value
while the SCL pin is HIGH will be interpreted as a
START or a STOP condition.
6.1.2
SERIAL CLOCK (SCL)
The Serial Clock (SCL) signal is the clock signal of the
device. The rising edge of the SCL signal latches the
value on the SDA pin. The MCP44XX supports three
I2C interface clock modes:
• Standard Mode: clock rates up to 100 kHz
• Fast Mode: clock rates up to 400 kHz
• High-Speed Mode (HS mode): clock rates up to
3.4 MHz
Host
Controller
SCL
SCL
SDA
SDA
The MCP44XX will not stretch the clock signal (SCL)
since memory read access occur fast enough.
I/O (1)
HVC/A0 (2)
Depending on the clock rate mode, the interface will
display different characteristics.
A1
(2, 3)
6.1.3
THE ADDRESS BITS (A1:A0)
Note 1: If High voltage commands are desired,
some type of external circuitry needs to
be implemented.
There are up to two hardware pins used to specify the
device address. The number of address pins is
determined by the part number.
2: These pins have internal pull-ups. If
faster rise times are required, then
external pull-ups should be added.
Address 0 is multiplexed with the High Voltage
Command (HVC) function. So the state of A0 is latched
on the MCP4XXX’s POR/BOR event.
3: This pin could be tied high, low, or
connected to an I/O pin of the Host
Controller.
The state of the A1 pin should be static, that is they
should be tied high or tied low.
FIGURE 6-1:
Diagram.
Typical I2C Interface Block
6.1.3.1
The High Voltage Command (HVC)
Signal
The High Voltage Command (HVC) signal is
multiplexed with Address 0 (A0) and is used to indicate
that the command, or sequence of commands, are in
the High Voltage mode. High Voltage commands allow
the device’s WiperLock Technology and write protect
features to be enabled and disabled.
The HVC pin has an internal resistor connection to the
MCP44XXs internal VDD signal.
© 2010 Microchip Technology Inc.
DS22265A-page 53
MCP444X/446X
6.2
I2C Operation
6.2.1.3
The MCP44XX’s I2C module is compatible with the
Philips I2C specification. The following lists some of the
modules features:
• 7-bit slave addressing
• Supports three clock rate modes:
- Standard mode, clock rates up to 100 kHz
- Fast mode, clock rates up to 400 kHz
- High-speed mode (HS mode), clock rates up
to 3.4 MHz
• Support Multi-Master Applications
• General call addressing
• Internal weak pull-ups on interface signals
The I2C 10-bit addressing mode is not supported.
The Philips I2C specification only defines the field
types, field lengths, timings, etc. of a frame. The frame
content defines the behavior of the device. The frame
content for the MCP44XX is defined in Section 7.0.
6.2.1
I2C BIT STATES AND SEQUENCE
Figure 6-8 shows the I2C transfer sequence. The serial
clock is generated by the master. The following definitions are used for the bit states:
• Start bit (S)
• Data bit
• Acknowledge (A) bit (driven low) /
No Acknowledge (A) bit (not driven low)
• Repeated Start bit (Sr)
• Stop bit (P)
6.2.1.1
2nd Bit
SCL
S
FIGURE 6-2:
6.2.1.2
Start Bit.
Data Bit
The SDA signal may change state while the SCL signal
is Low. While the SCL signal is High, the SDA signal
MUST be stable (see Figure 6-5).
SDA
1st Bit
SCL
DS22265A-page 54
SCL
FIGURE 6-4:
2nd Bit
Data Bit.
D0
A
8
9
Acknowledge Waveform.
Not A (A) Response
The A bit has the SDA signal high. Table 6-1 shows
some of the conditions where the Slave Device will
issue a Not A (A).
If an error condition occurs (such as an A instead of A),
then an START bit must be issued to reset the
command state machine.
MCP45XX/MCP46XX A / A
RESPONSES
Acknowledge
Bit
Response
Comment
General Call
A
Slave Address
valid
A
Slave Address
not valid
A
Device Memory Address
and specified
command
(AD3:AD0 and
C1:C0) are an
invalid combination
A
After device has
received address
and command
Communication during
EEPROM write
cycle
A
After device has
received address
and command,
and valid conditions for EEPROM
write
N.A.
I2C Module
Resets, or a “Don’t
Care” if the collision occurs on the
Master’s “Start bit”
Bus Collision
Data Bit
FIGURE 6-3:
SDA
Event
The Start bit (see Figure 6-2) indicates the beginning of
a data transfer sequence. The Start bit is defined as the
SDA signal falling when the SCL signal is “High”.
1st Bit
The A bit (see Figure 6-4) is typically a response from
the receiving device to the transmitting device.
Depending on the context of the transfer sequence, the
A bit may indicate different things. Typically the Slave
device will supply an A response after the Start bit and
8 “data” bits have been received. an A bit has the SDA
signal low.
TABLE 6-1:
Start Bit
SDA
Acknowledge (A) Bit
Only if GCEN bit is
set
© 2010 Microchip Technology Inc.
MCP444X/446X
6.2.1.4
6.2.1.5
Repeated Start Bit
The Repeated Start bit (see Figure 6-5) indicates the
current Master Device wishes to continue communicating with the current Slave Device without releasing the
I2C bus. The Repeated Start condition is the same as
the Start condition, except that the Repeated Start bit
follows a Start bit (with the Data bits + A bit) and not a
Stop bit.
The Stop bit (see Figure 6-6) Indicates the end of the
I2C Data Transfer Sequence. The Stop bit is defined as
the SDA signal rising when the SCL signal is “High”.
A Stop bit resets the I2C interface of all MCP44XX
devices.
SDA A / A
The Start bit is the beginning of a data transfer
sequence and is defined as the SDA signal falling when
the SCL signal is “High”.
SCL
P
Note 1: A bus collision during the Repeated Start
condition occurs if:
FIGURE 6-6:
Transmit Mode.
• SDA is sampled low when SCL goes
from low to high.
6.2.2
• SCL goes low before SDA is asserted
low. This may indicate that another
master is attempting to transmit a
data "1".
CLOCK STRETCHING
The MCP44XX will not stretch the clock signal (SCL)
since memory read access occur fast enough.
6.2.3
ABORTING A TRANSMISSION
If any part of the I2C transmission does not meet the
command format, it is aborted. This can be intentionally
accomplished with a START or STOP condition. This is
done so that noisy transmissions (usually an extra
START or STOP condition) are aborted before they
corrupt the device.
SCL
Sr = Repeated Start
FIGURE 6-5:
Waveform.
Stop Condition Receive or
“Clock Stretching” is something that the receiving
Device can do, to allow additional time to “respond” to
the “data” that has been received.
1st Bit
SDA
Stop Bit
Repeat Start Condition
SDA
SCL
S
FIGURE 6-7:
1st Bit
2nd Bit 3rd Bit
4th Bit
5th Bit
6th Bit
7th Bit
8th Bit
A/A
P
Typical 8-Bit I2C Waveform Format.
SDA
SCL
START
Condition
FIGURE 6-8:
Data allowed
to change
Data or
A valid
STOP
Condition
I2C Data States and Bit Sequence.
© 2010 Microchip Technology Inc.
DS22265A-page 55
MCP444X/446X
6.2.4
ADDRESSING
The address byte is the first byte received following the
START condition from the master device. The address
contains four (or more) fixed bits and (up to) three user
defined hardware address bits (pins A1 and A0). These
7-bits address the desired I2C device. The A6:A2
address bits are fixed to “01011” and the device
appends the value of following two address pins (A1
and A0).
Since there are address bits controlled by hardware
pins, there may be up to four MCP44XX devices on the
same I2C bus.
Figure 6-9 shows the slave address byte format, which
contains the seven address bits. There is also a read/
write (R/W) bit. Table 6-2 shows the fixed address for
device.
Hardware Address Pins
The hardware address bits (A1, and A0) correspond to
the logic level on the associated address pins. This
allows up to eight devices on the bus.
Slave Address
S A6 A5 A4 A3 A2 A1 A0 R/W
“0” “1” “0” “1” “1”
See Table 6-2
Start
bit
A/A
R/W bit
R/W = 0 = write
R/W = 1 = read
A bit (controlled by slave device)
A = 0 = Slave Device Acknowledges byte
A = 1 = Slave Device does not Acknowledge byte
FIGURE 6-9:
I2C Control Byte.
TABLE 6-2:
Slave Address Bits in the
DEVICE SLAVE ADDRESSES
Device
Address
MCP44XX ‘0101 1’b + A1:A0
Note 1:
Comment
Supports up to 4
devices. (Note 1)
A0 is used for High-Voltage commands
(HVC/A0) and the value is latched at
POR/BOR.
These pins have a weak pull-up enabled when the VDD
< VBOR. The weak pull-up utilizes the “smart” pull-up
technology and exhibits the same characteristics as the
High-voltage tolerant I/O structure.
6.2.5
The state of the A0 address pin is latch on POR/BOR.
This is required since High Voltage commands force
this pin (HVC/A0) to the VIHH level.
As the device transitions from HS mode to FS mode,
the slope control parameter will change from the HS
specification to the FS specification.
SLOPE CONTROL
The MCP44XX implements slope control on the SDA
output.
For Fast (FS) and High-Speed (HS) modes, the device
has a spike suppression and a Schmidt trigger at SDA
and SCL inputs.
DS22265A-page 56
© 2010 Microchip Technology Inc.
MCP444X/446X
6.2.6
HS MODE
After switching to the High-Speed mode, the next
transferred byte is the I2C control byte, which specifies
the device to communicate with, and any number of
data bytes plus acknowledgements. The Master
Device can then either issue a Repeated Start bit to
address a different device (at High-Speed) or a Stop bit
to return to Fast/Standard bus speed. After the Stop bit,
any other Master Device (in a Multi-Master system) can
arbitrate for the I2C bus.
2
The I C specification requires that a high-speed mode
device must be ‘activated’ to operate in high-speed
(3.4 Mbit/s) mode. This is done by the Master sending
a special address byte following the START bit. This
byte is referred to as the high-speed Master Mode
Code (HSMMC).
The MCP44XX device does not acknowledge this byte.
However, upon receiving this command, the device
switches to HS mode. The device can now
communicate at up to 3.4 Mbit/s on SDA and SCL
lines. The device will switch out of the HS mode on the
next STOP condition.
See Figure 6-10 for illustration of HS mode command
sequence.
For more information on the HS mode, or other I2C
modes, please refer to the Phillips I2C specification.
The master code is sent as follows:
1.
2.
3.
6.2.6.1
START condition (S)
High-Speed Master Mode Code (0000 1XXX),
The XXX bits are unique to the high-speed (HS)
mode Master.
No Acknowledge (A)
Slope Control
The slope control on the SDA output is different
between the Fast/Standard Speed and the High-Speed
clock modes of the interface.
6.2.6.2
Pulse Gobbler
The pulse gobbler on the SCL pin is automatically
adjusted to suppress spikes < 10 ns during HS mode.
F/S-mode
HS-mode
S ‘0 0 0 0 1 X X X’b
P
A Sr ‘Slave Address’ R/W A
HS Select Byte
Control Byte
“Data”
Command/Data Byte(s)
S = Start bit
Sr = Repeated Start bit
A = Acknowledge bit
A = Not Acknowledge bit
R/W = Read/Write bit
P = Stop bit (Stop condition terminates HS Mode)
FIGURE 6-10:
A/A
F/S-mode
HS-mode continues
Sr ‘Slave Address’ R/W A
Control Byte
HS Mode Sequence.
© 2010 Microchip Technology Inc.
DS22265A-page 57
MCP444X/446X
6.2.7
GENERAL CALL
The General Call is a method that the “Master” device
can communicate with all other “Slave” devices. In a
Multi-Master application, the other Master devices are
operating in Slave mode. The General Call address
has two documented formats. These are shown in
Figure 6-11. We have added a MCP44XX format in this
figure as well.
This will allow customers to have multiple I2C Digital
Potentiometers on the bus and have them operate in a
synchronous fashion (analogous to the DAC Sync pin
functionality). If these MCP44XX 7-bit commands
conflict with other I2C devices on the bus, then the
customer will need two I2C busses and ensure that the
devices are on the correct bus for their desired
application functionality.
Dual Pot devices can not update both Pot0 and Pot1
from a single command. To address this, there are
General Call commands for the Wiper 0, Wiper 1, and
the TCON registers.
Table 6-3 shows the General Call Commands. Three
commands are specified by the I2C specification and
are not applicable to the MCP44XX (so command is
Not Acknowledged) The MCP44XX General Call
Commands are Acknowledge. Any other command is
Not Acknowledged.
Note:
Only one General Call command per issue
of the General Call control byte. Any
additional General Call commands are
ignored and Not Acknowledged.
DS22265A-page 58
TABLE 6-3:
7-bit
Command
GENERAL CALL COMMANDS
Comment
(1, 2, 3)
‘1000 00d’b Write Next Byte (Third Byte) to Volatile
Wiper 0 Register
‘1001 00d’b Write Next Byte (Third Byte) to Volatile
Wiper 1 Register
‘1100 00d’b Write Next Byte (Third Byte) to TCON
Register
‘1000 010’b Increment Wiper 0 Register
or
‘1000 011’b
‘1001 010’b Increment Wiper 1 Register
or
‘1001 011’b
‘1000 100’b Decrement Wiper 0 Register
or
‘1000 101’b
‘1001 100’b Decrement Wiper 1 Register
or
‘1001 101’b
Note 1:
2:
3:
Any other code is Not Acknowledged.
These codes may be used by other
devices on the I2C bus.
The 7-bit command always appends a “0”
to form 8-bits.
“d” is the D8 bit for the 9-bit write value.
© 2010 Microchip Technology Inc.
MCP444X/446X
Second Byte
S 0 0
0
0
0 0
0
0 A X X X X X
General Call Address
X
X
0
A P
“7-bit Command”
Reserved 7-bit Commands (By I2C Specification - Philips # 9398 393 40011, Ver. 2.1 January 2000)
‘0000 011’b - Reset and write programmable part of slave address by hardware.
‘0000 010’b - Write programmable part of slave address by hardware.
‘0000 000’b - NOT Allowed
MCP44XX 7-bit Commands
‘1000 01x’b - Increment Wiper 0 Register.
‘1001 01x’b - Increment Wiper 1 Register.
‘1000 10x’b - Decrement Wiper 0 Register.
‘1001 10x’b - Decrement Wiper 1 Register.
The Following is a Microchip Extension to this General Call Format
Second Byte
S 0
0 0
0
0 0
0
0 A X X X X X
General Call Address
X d
0
Third Byte
A d
“7-bit Command”
d
d
d
d
d
d
d A P
“0” for General Call Command
MCP44XX 7-bit Commands
‘1000 00d’b - Write Next Byte (Third Byte) to Volatile Wiper 0 Register.
‘1001 00d’b - Write Next Byte (Third Byte) to Volatile Wiper 1 Register.
‘1100 00d’b - Write Next Byte (Third Byte) to TCON Register.
The Following is a “Hardware General Call” Format
Second Byte
S 0
0 0
0
0
0 0
General Call Address
FIGURE 6-11:
0
A X X X X X
“7-bit Command”
X
n occurrences of (Data + A)
X
1
A X X X X X X X X A P
This indicates a “Hardware General Call”
MCP44XX will ignore this byte and
all following bytes (and A), until
a Stop bit (P) is encountered.
General Call Formats.
© 2010 Microchip Technology Inc.
DS22265A-page 59
MCP444X/446X
NOTES:
DS22265A-page 60
© 2010 Microchip Technology Inc.
MCP444X/446X
7.0
DEVICE COMMANDS
The MCP44XX’s I2C command formats are specified in
this section. The I2C protocol does not specify how
commands are formatted.
The MCP44XX supports four basic commands. The
location accessed determines the commands that are
supported.
For the Volatile Wiper Registers, these commands are:
•
•
•
•
For the Nonvolatile wiper EEPROM, general purpose
data EEPROM, and the TCON Register, these
commands are:
• Write Data
• Read Data
These commands have formats for both a single
command or continuous commands. These commands
are shown in Table 7-1.
Each command has two operational states. The
operational state determines if the device commands
control the special features (Write Protect and
WiperLock Technology). These operational states are
referred to as:
• Normal Serial Commands
• High-Voltage Serial Commands
I2C COMMANDS
Command
Operation
Mode
Write Data
Single
Read Data
Single
Continuous
# of Bit
Clocks (1)
29
18n + 11
29
Random
Continuous
(3)
Continuous
Decrement
(3)
2:
3:
Operates on
Volatile/
Nonvolatile
memory
Both
Volatile Only
Both
Both
Both (2)
20
Volatile Only
9n + 11
Volatile Only
20
Volatile Only
9n + 11
Volatile Only
Single
Continuous
Note 1:
48
18n + 11
Single
Increment
Additionally, there are two commands used to enable
or disable the special features (Write Protect and Wiper
Lock Technology) of the device. The commands are
special cases of the Increment and Decrement
High-Voltage Serial Command.
Table 7-2 shows the supported commands for each
memory location.
Write Data
Read Data
Increment Data
Decrement Data
TABLE 7-1:
Normal serial commands are those where the HVC pin
is driven to VIH or VIL. With High-Voltage Serial
Commands, the HVC pin is driven to VIHH. In each
mode, there are four possible commands.
“n” indicates the number of times the
command operation is to be repeated.
This command is useful to determine if a
nonvolatile memory write cycle has
completed.
High Voltage Increment and Decrement
commands on select nonvolatile memory
locations enable/disable WiperLock
Technology and the software Write
Protect feature.
© 2010 Microchip Technology Inc.
Table 7-3 shows an overview of all the device
commands and their interaction with other device
features.
7.1
Command Byte
The MCP44XX’s Command Byte has three fields: the
Address, the Command Operation, and 2 Data bits
(see Figure 7-1). Currently only one of the data bits is
defined (D8).
The device memory is accessed when the Master
sends a proper Command Byte to select the desired
operation. The memory location getting accessed is
contained in the Command Byte’s AD3:AD0 bits. The
action desired is contained in the Command Byte’s
C1:C0 bits, see Figure 7-1. C1:C0 determines if the
desired memory location will be read, written,
Incremented (wiper setting +1) or Decremented (wiper
setting -1). The Increment and Decrement commands
are only valid on the volatile wiper registers, and in
High Voltage commands to enable/disable WiperLock
Technology and Software Write Protect.
If the Address bits and Command bits are not a valid
combination, then the MCP44XX will generate a Not
Acknowledge pulse to indicate the invalid combination.
The I2C Master device must then force a Start
Condition to reset the MCP44XX’s I2C module.
D9 and D8 are the most significant bits for the digital
potentiometer’s wiper setting. The 8-bit devices utilize
D8 as their MSb while the 7-bit devices utilize D7 (from
the data byte) as their MSb.
COMMAND BYTE
A A A A A C C D D A
D D D D 1 0 9 8
3 2 1 0
MSbits (Data)
MCP4XXX
Memory Address
Command Operation bits
00 = Write Data
01 = Increment
10 = Decrement
11 = Read Data
FIGURE 7-1:
Command Byte Format.
DS22265A-page 61
MCP444X/446X
TABLE 7-2:
MEMORY MAP AND THE SUPPORTED COMMANDS
Address
Function
Volatile Wiper 0
Value
00h
Command
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
Increment Wiper
Decrement Wiper
01h
Volatile Wiper 1
NV Wiper 0
03h
NV Wiper 1
—
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
Decrement Wiper
—
—
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
High Voltage Increment
—
Wiper Lock 0 Disable (4)
High Voltage Decrement
—
Wiper Lock 0 Enable (5)
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
High Voltage Increment
—
Wiper Lock 1 Disable (4)
High Voltage Decrement
—
Wiper Lock 1 Enable (5)
04h (2) Volatile
TCON 0 Register
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
05h (2)
Read Data (3)
nn nnnn nnnn
Write Data
Read Data (3)
nn nnnn nnnn
nn nnnn nnnn
Status Register
Volatile Wiper 2
06h
Increment Wiper
Decrement Wiper
07h
Volatile Wiper 3
Write Data
Read Data (3)
Increment Wiper
Decrement Wiper
08h
NV Wiper 2
Write Data
Read Data (3)
High Voltage Increment
High Voltage Decrement
09h
NV Wiper 3
0Ah (2)
Volatile
TCON 1 Register
0Bh (2) Data EEPROM
Write Data
Read Data (3)
—
—
nn nnnn nnnn
nn nnnn nnnn
—
—
nn nnnn nnnn
nn nnnn nnnn
—
Wiper Lock 2 Disable (4)
—
Wiper Lock 2 Enable (5)
nn nnnn nnnn
nn nnnn nnnn
High Voltage Increment
—
Wiper Lock 3 Disable (4)
High Voltage Decrement
—
Wiper Lock 3 Enable (5)
Write Data
Read Data (3)
nn nnnn nnnn
nn nnnn nnnn
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
0Ch (2) Data EEPROM
Write Data
Read Data (3)
nn nnnn nnnn
nn nnnn nnnn
0Dh (2) Data EEPROM
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
Write Data
Read Data (3)
nn nnnn nnnn
nn nnnn nnnn
0Eh (2) Data EEPROM
0Fh
Note
Data EEPROM
1:
2:
3:
4:
5:
Comment
—
Write Data
Increment Wiper
02h
Data
(10-bits) (1)
Write Data
nn nnnn nnnn
Read Data (3)
nn nnnn nnnn
High Voltage Increment
—
Write Protect Disable (4)
High Voltage Decrement
—
Write Protect Enable (5)
The Data Memory is only 9-bits wide, so the MSb is ignored by the device.
Increment or Decrement commands are invalid for these addresses.
I2C read operation will read 2 bytes, of which the 10-bits of data are contained within.
Disables WiperLock Technology for wiper 0, wiper 1, wiper 2, wiper3, or disables Write Protect.
Enables WiperLock Technology for wiper 0, wiper 1, wiper 2, wiper3, or enables Write Protect.
DS22265A-page 62
© 2010 Microchip Technology Inc.
MCP444X/446X
7.2
Data Byte
7.3
Only the Read Command and the Write Command
have Data Byte(s).
The Write command concatenates the 8 bits of the
Data Byte with the one data bit (D8) contained in the
Command Byte to form 9 bits of data (D8:D0). The
Command Byte format supports up to 9 bits of data so
that the 8-bit resistor network can be set to Full-Scale
(100h or greater). This allows wiper connections to
Terminal A and to Terminal B. The D9 bit is currently
unused.
Error Condition
If the four address bits received (AD3:AD0) and the two
command bits received (C1:C0) are a valid
combination, the MCP44XX will Acknowledge the I2C
bus.
If the address bits and command bits are an invalid
combination, then the MCP44XX will Not Acknowledge
the I2C bus.
Once an error condition has occurred, any following
commands are ignored until the I2C bus is reset with a
Start Condition.
7.3.1
ABORTING A TRANSMISSION
A Restart or Stop condition in the expected data bit
position will abort the current command sequence and
data will not be written to the MCP44XX.
TABLE 7-3:
COMMANDS
Command Name
Writes
Operates on Volatile/
Value in
Nonvolatile memory
EEPROM
High
Voltage
(VIHH) on
HVC pin?
Impact on
WiperLock or
Write Protect
Works
when
Wiper is
“locked”?
Write Data
Yes (1)
Both
—
unlocked (1)
No
Read Data
—
Both
—
unlocked (1)
No
(1)
No
No
Increment Wiper
—
Volatile Only
—
unlocked
Decrement Wiper
—
Volatile Only
—
unlocked (1)
High Voltage Write Data
Yes
Both
Yes
unchanged
No
High Voltage Read Data
—
Both
Yes
unchanged
Yes
High Voltage Increment Wiper
—
Volatile Only
Yes
unchanged
No
High Voltage Decrement Wiper
—
Volatile Only
Yes
unchanged
No
Modify Write Protect or WiperLock
Technology (High Voltage) - Enable
— (2)
Nonvolatile Only (2)
Yes
locked/
protected (2)
Yes
Modify Write Protect or WiperLock
Technology (High Voltage) - Disable
— (3)
Nonvolatile Only (3)
Yes
unlocked/
unprotected (3)
Yes
Note 1:
2:
3:
This command will only complete, if wiper is “unlocked” (WiperLock Technology is Disabled).
If the command is executed using address 02h, 03h 08h, or 09h; that corresponding wiper is locked or
if with address 0Fh, then Write Protect is enabled.
If the command is executed using with address 02h, 03h 08h, or 09h; that corresponding wiper is unlocked
or if with address 0Fh, then Write Protect is disabled.
© 2010 Microchip Technology Inc.
DS22265A-page 63
MCP444X/446X
7.4
Write Data
Normal and High Voltage
The Write Command can be issued to both the Volatile
and Nonvolatile memory locations. The format of the
command, see Figure 7-2, includes the I2C Control
Byte, an A bit, the MCP44XX Command Byte, an A bit,
the MCP44XX Data Byte, an A bit, and a Stop (or
Restart) condition. The MCP44XX generates the A / A
bits.
A Write command to a Volatile memory location
changes that location after a properly formatted Write
Command and the A / A clock have been received.
A Write command to a Nonvolatile memory location will
only start a write cycle after a properly formatted Write
Command have been received and the Stop condition
has occurred.
Note:
7.4.1
Writes to certain memory locations will be
dependant on the state of the WiperLock
Technology bits and the Write Protect bit.
SINGLE WRITE TO VOLATILE
MEMORY
For volatile memory locations, data is written to the
MCP44XX after every byte transfer (during the
Acknowledge). If a Stop or Restart condition is
generated during a data transfer (before the A), the
data will not be written to the MCP44XX. After the A bit,
the master can initiate the next sequence with a Stop or
Restart condition.
7.4.3
CONTINUOUS WRITES TO
VOLATILE MEMORY
A continuous write mode of operation is possible when
writing to the volatile memory registers (address 00h,
01h, 04h, 06h, 07h, and 0Ah). This continuous write
mode allows writes without a Stop or Restart condition
or repeated transmissions of the I2C Control Byte.
Figure 7-3 shows the sequence for three continuous
writes. The writes do not need to be to the same volatile
memory address. The sequence ends with the master
sending a STOP or RESTART condition.
7.4.4
CONTINUOUS WRITES TO
NONVOLATILE MEMORY
If a continuous write is attempted on Nonvolatile
memory, the missing Stop condition will cause the
command to be an error condition (A). A Start bit is
required to reset the command state machine.
7.4.5
THE HIGH VOLTAGE COMMAND
(HVC) SIGNAL
The High Voltage Command (HVC) signal is
multiplexed with Address 0 (A0) and is used to indicate
that the command, or sequence of commands, are in
the High Voltage operational state. High Voltage
commands allow the device’s WiperLock Technology
and write protect features to be enabled and disabled.
The HVC pin has an internal resistor connection to the
MCP44XXs internal VDD signal.
Refer to Figure 7-2 for the byte write sequence.
7.4.2
SINGLE WRITE TO NONVOLATILE
MEMORY
The sequence to write to a single nonvolatile memory
location is the same as a single write to volatile memory
with the exception that the EEPROM write cycle (twc) is
started after a properly formatted command, including
the Stop bit, is received. After the Stop condition
occurs, the serial interface may immediately be
re-enabled by initiating a Start condition.
During an EEPROM write cycle, access to the volatile
memory (addresses 00h, 01h, 04h, 05h, 06h, 07h, and
0Ah) is allowed when using the appropriate command
sequence. Commands that address nonvolatile
memory are ignored until the EEPROM write cycle (twc)
completes. This allows the Host Controller to operate
on the Volatile Wiper registers, the TCON register, and
to Read the Status Register. The EEWA bit in the
Status register indicates the status of an EEPROM
Write Cycle.
Once a write command to a Nonvolatile memory
location has been received, no other commands should
be received before the Stop condition occurs.
Figure 7-2 shows the waveform for a single write.
DS22265A-page 64
© 2010 Microchip Technology Inc.
MCP444X/446X
Write bit
Variable
Address
Fixed
Address
S 0
1
0 1
1 A1 A0 0
A
Device
Memory
Address
AD AD AD AD
3 2 1 0 0
0 x D8 A D7 D6 D5 D4 D3 D2 D1 D0 A P
WRITE Command
Control Byte
Write bit
Variable
Address
Fixed
Address
1
0 1
1 A1 A0 0 A
Device
Memory
Address
0 x D8 A D7 D6 D5 D4 D3 D2 D1 D0 A
WRITE Command
AD AD AD AD
3 2 1 0 0
Write Data bits
0 x D8 A D7 D6 D5 D4 D3 D2 D1 D0 A
WRITE Command
AD AD AD AD
3 2 1 0 0
Write Data bits
STOP bit
0 x D8 A D7 D6 D5 D4 D3 D2 D1 D0 A P
WRITE Command
FIGURE 7-3:
Write “Data” bits
Command
AD AD AD AD
3 2 1 0 0
Control Byte
Note:
Write Data bits
I2C Write Sequence.
FIGURE 7-2:
S 0
Write “Data” bits
Command
Write Data bits
Only functions when writing the volatile wiper registers (AD3:AD0 = 00h, 01h, 06h, and
07h) or the TCON registers (AD3:AD0 = 04h and 0Ah)
I2C Continuous Volatile Wiper Write.
© 2010 Microchip Technology Inc.
DS22265A-page 65
MCP444X/446X
7.5
Read Data
Normal and High Voltage
The Read Command can be issued to both the Volatile
and Nonvolatile memory locations. The format of the
command (see Figure 7-4), includes the Start condition, I2C Control Byte (with R/W bit set to “0”), A bit,
MCP44XX Command Byte, A bit, followed by a
Repeated Start bit, I2C Control Byte (with R/W bit set to
“1”), and the MCP44XX transmitting the requested
Data High Byte, and A bit, the Data Low Byte, the
Master generating the A, and Stop condition.
The I2C Control Byte requires the R/W bit equal to a
logic one (R/W = 1) to generate a read sequence. The
memory location read will be the last address
contained in a valid write MCP44XX Command Byte or
address 00h if no write operations have occurred since
the device was reset (Power-on Reset or Brown-out
Reset).
During a write cycle (Write or High Voltage Write to a
Nonvolatile memory location) the Read command can
only read the Volatile memory locations. By reading the
Status Register (05h), the Host Controller can
determine when the write cycle has completed (via the
state of the EEWA bit).
Read operations initially include the same address byte
sequence as the write sequence (shown in Figure 6-9).
This sequence is followed by another control byte
(including the Start condition and Acknowledge) with
the R/W bit equal to a logic one (R/W = 1) to indicate a
read. The MCP44XX will then transmit the data
contained in the addressed register. This is followed by
the master generating an A bit in preparation for more
data, or an A bit followed by a Stop. The sequence is
ended with the master generating a Stop or Restart
condition.
7.5.2
CONTINUOUS READS
Continuous reads allows the devices memory to be
read quickly. Continuous reads are possible to all
memory locations. If a nonvolatile memory write cycle
is occurring, then Read commands may only access
the volatile memory locations.
Figure 7-6 shows the sequence for three continuous
reads.
For continuous reads, instead of transmitting a Stop
or Restart condition after the data transfer, the master
reads the next data byte. The sequence ends with the
master Not Acknowledging and then sending a Stop or
Restart.
7.5.3
THE HIGH VOLTAGE COMMAND
(HVC) SIGNAL
The High Voltage Command (HVC) signal is
multiplexed with Address 0 (A0) and is used to indicate
that the command, or sequence of commands, are in
the High Voltage mode. High Voltage commands allow
the device’s WiperLock Technology and write protect
features to be enabled and disabled.
The HVC pin has an internal resistor connection to the
MCP44XX’s internal VDD signal.
7.5.4
IGNORING AN I2C TRANSMISSION
AND “FALLING OFF” THE BUS
The MCP44XX expects to receive complete, valid I2C
commands and will assume any command not defined
as a valid command is due to a bus corruption and will
enter a passive high condition on the SDA signal. All
signals will be ignored until the next valid Start
condition and Control Byte are received.
The internal address pointer is maintained. If this
address pointer is for a nonvolatile memory address
and the read control byte addresses the device during
a Nonvolatile Write Cycle (tWC) the device will respond
with an A bit.
7.5.1
SINGLE READ
Figure 7-4 show the waveforms for a single read.
For single reads the master sends a STOP or
RESTART condition after the data byte is sent from the
slave.
7.5.1.1
Random Read
Figure 7-5 shows the sequence for a Random Reads.
Refer to Figure 7-5 for the random byte read
sequence.
DS22265A-page 66
© 2010 Microchip Technology Inc.
MCP444X/446X
Read bit
S 0
1
STOP bit
Variable
Address
Fixed
Address
0 1
Read Data bits
1 A1 A0 1
A 0
0
0
0 D8 A1 D7 D6 D5 D4 D3 D2 D1 D0 A2
0 0 0
P
Read bits
Control Byte
Note 1: Master Device is responsible for A / A signal. If a A signal occurs, the MCP44XX will abort this
transfer and release the bus.
2: The Master Device will Not Acknowledge, and the MCP44XX will release the bus so the
Master Device can generate a Stop or Repeated Start condition.
3: The MCP44XX retains the last “Device Memory Address” that it has received. This is the
MCP44XX does not “corrupt” the “Device Memory Address” after Repeated Start or Stop
conditions.
4: The Device Memory Address pointer defaults to 00h on POR and BOR conditions.
I2C Read (Last Memory Address Accessed).
FIGURE 7-4:
Write bit
Variable
Address
Fixed
Address
S 0 1
0
1
1 A1 A0 0
Repeated Start bit
Device
Memory
Address
A
Command
AD AD AD AD
3 2 1 0 1
1
x X A Sr
READ Command
Control Byte
STOP bit
Read bit
0
1 0
1
1 A1 A0 1
A 0
Control Byte
Read Data bits
0
0
0 0 0
0 D8 A1 D7 D6 D5 D4 D3 D2 D1 D0 A2
P
Read bits
Note 1: Master Device is responsible for A / A signal. If a A signal occurs, the MCP44XX will abort this
transfer and release the bus.
2: The Master Device will Not Acknowledge, and the MCP44XX will release the bus so the Master Device can generate a Stop or Repeated Start condition.
3: The MCP44XX retains the last “Device Memory Address” that it has received. This is the
MCP44XX does not “corrupt” the “Device Memory Address” after Repeated Start or Stop
conditions.
FIGURE 7-5:
I2C Random Read.
© 2010 Microchip Technology Inc.
DS22265A-page 67
MCP444X/446X
Read bit
Variable
Address
Fixed
Address
S 0 1
0
1
Read Data bits
0
1 A1 A0 1 A
0
0
0 0 0
0 D8 A1 D7 D6 D5 D4 D3 D2 D1 D0 A1
Read bits
Control Byte
Read Data bits
0
0
0
0 0 0
0 D8 A1 D7 D6 D5 D4 D3 D2 D1 D0 A1
STOP bit
Read Data bits
0
0
0
0 0 0
0 D8 A1 D7 D6 D5 D4 D3 D2 D1 D0 A2
P
Note 1: Master Device is responsible for A / A signal. If a A signal occurs, the MCP44XX will abort this
transfer and release the bus.
2: The Master Device will Not Acknowledge, and the MCP44XX will release the bus so the
Master Device can generate a Stop or Repeated Start condition.
FIGURE 7-6:
DS22265A-page 68
I2C Continuos Reads.
© 2010 Microchip Technology Inc.
MCP444X/446X
7.6
The advantage of using an Increment Command
instead of a read-modify-write series of commands is
speed and simplicity. The wiper will transition after each
Command Acknowledge when accessing the volatile
wiper registers.
Increment Wiper
Normal and High Voltage
The Increment Command provides a quick and easy
method to modify the potentiometer’s wiper by +1 with
minimal overhead. The Increment Command will only
function on the volatile wiper setting memory locations
00h, 01h, 06h and 07h. The Increment Command to
Nonvolatile addresses will be ignored and will generate
a A.
TABLE 7-4:
Current Wiper
Setting
Table 7-4 shows the valid addresses for
the Increment Wiper command. Other
addresses are invalid.
Note:
INCREMENT OPERATION VS.
VOLATILE WIPER VALUE
Increment
Command
Operates?
Wiper (W)
Properties
7-bit
Pot
8-bit
Pot
When executing an Increment Command, the volatile
wiper setting will be altered from n to n+1 for each
Increment Command received. The value will
increment up to 100h max on 8-bit devices and 80h on
7-bit devices. If multiple Increment Commands are
received after the value has reached 100h (or 80h), the
value will not be incremented further. Table 7-4 shows
the Increment Command versus the current volatile
wiper value.
3FFh
081h
3FFh
101h
Reserved
No
(Full-Scale (W = A))
080h
100h
Full-Scale (W = A)
07Fh
041h
0FFh
081
W=N
040h
080h
W = N (Mid-Scale)
03Fh
001h
07Fh
001
W=N
The Increment Command will most commonly be
performed on the Volatile Wiper locations until a
desired condition is met. The value in the Volatile Wiper
register would need to be read using a Read operation
in order to write the new setting to the corresponding
Nonvolatile wiper memory using a Write operation. The
MCP44XX is responsible for generating the A bits.
000h
000h
Zero Scale (W = B) Yes
7.6.1
Note:
The command sequence can go from an
increment to any other valid command for
the specified address. Issuing an
increment or decrement to a nonvolatile
location will cause an error condition (A
will be generated).
Fixed
Address
S 0
1
0 1
Write bit
Variable
Address
1 A1 A0 0
Control Byte
A
Device
Memory
Address
Yes
THE HIGH VOLTAGE COMMAND
(HVC) SIGNAL
The High Voltage Command (HVC) signal is
multiplexed with Address 0 (A0) and is used to indicate
that the command, or sequence of commands, are in
the High Voltage mode. Signals > VIHH (~8.5V) on the
HVC/A0 pin puts MCP44XX devices into High Voltage
mode. High Voltage commands allow the device’s
WiperLock Technology and write protect features to be
enabled and disabled.
Refer to Figure 7-7 for the Increment Command
sequence. The sequence is terminated by the Stop
condition. So when executing a continuous command
string, the Increment command can be followed by any
other valid command. This means that writes do not
need to be to the same volatile memory address.
Note:
No
There is a required delay after the HVC pin
is driven to the VIHH level to the 1st edge
of the SCL pin.
The HVC pin has an internal resistor connection to the
MCP44XX’s internal VDD signal.
Command
AD AD AD AD
3 2 1 0 0
1 x
AD AD AD AD
X A 4 3 2 1 0
INCR Command (n+1)
1 x
X A P (2)
INCR Command (n+2)
Note1: Increment Command (INCR) only functions when accessing the volatile wiper
registers (AD3:AD0 = 00h, 01h, 06h, and 07h).
2: This command sequence does not need to terminate (using the Stop bit) and can
change to any other desired command sequence (Increment, Read, or Write).
FIGURE 7-7:
I2C Increment Command Sequence.
© 2010 Microchip Technology Inc.
DS22265A-page 69
MCP444X/446X
7.7
Decrement Wiper
Normal and High Voltage
The Decrement Command provides a quick and easy
method to modify the potentiometer’s wiper by -1 with
minimal overhead. The Decrement Command will only
function on the volatile wiper setting memory locations
00h and 01h. Decrement Commands to Nonvolatile
addresses will be ignored and will generate an A bit.
Note:
The advantage of using a Decrement Command
instead of a read-modify-write series of commands is
speed and simplicity. The wiper will transition after each
Command Acknowledge when accessing the volatile
wiper registers.
TABLE 7-5:
Current Wiper
Setting
Table 7-5 shows the valid addresses for
the Decrement Wiper command. Other
addresses are invalid.
When executing a Decrement Command, the volatile
wiper setting will be altered from n to n-1 for each
Decrement Command received. The value will
decrement down to 000h min. If multiple Decrement
Commands are received after the value has reached
000h, the value will not be decremented further.
Table 7-5 shows the Increment Command versus the
current volatile wiper value.
The Decrement Command will most commonly be
performed on the Volatile Wiper locations until a
desired condition is met. The value in the Volatile Wiper
register would need to be read using a Read operation
in order to write the new setting to the corresponding
Nonvolatile wiper memory using a Write operation. The
MCP44XX is responsible for generating the A bits.
Refer to Figure 7-8 for the Decrement Command
sequence. The sequence is terminated by the Stop
condition. So when executing a continuous command
string, the Increment command can be followed by any
other valid command. This means that writes do not
need to be to the same volatile memory address.
Note:
The command sequence can go from an
increment to any other valid command for
the specified address. Issuing an
increment or decrement to a nonvolatile
location will cause an error condition (A
will be generated).
Fixed
Address
S 0 1
0
1
Write bit
Variable
Address
1 A1 A0 0 A
Control Byte
DECREMENT OPERATION VS.
VOLATILE WIPER VALUE
Wiper (W)
Properties
Decrement
Command
Operates?
7-bit
Pot
8-bit
Pot
3FFh
081h
3FFh
101h
Reserved
No
(Full-Scale (W = A))
080h
100h
Full-Scale (W = A)
07Fh
041h
0FFh
081
W=N
040h
080h
W = N (Mid-Scale)
03Fh
001h
07Fh
001
W=N
000h
000h
Zero Scale (W = B) No
7.7.1
Yes
Yes
THE HIGH VOLTAGE COMMAND
(HVC) SIGNAL
The High Voltage Command (HVC) signal is
multiplexed with Address 0 (A0) and is used to indicate
that the command, or sequence of commands, are in
the High Voltage mode. Signals > VIHH (~8.5V) on the
HVC/A0 pin puts MCP44XX devices into High Voltage
mode. High Voltage commands allow the device’s
WiperLock Technology and write protect features to be
enabled and disabled.
Note:
There is a required delay after the HVC pin
is driven to the VIHH level to the 1st edge
of the SCL pin.
The HVC pin has an internal resistor connection to the
MCP44XX’s internal VDD signal.
Device
Memory
Address Command
AD AD AD AD
3 2 1 0 1
AD AD AD AD
0 X X A 4 3 2 1 1
DECR Command (n-1)
0 X X A P (2)
DECR Command (n-2)
Note1: Decrement Command (DECR) only functions when accessing the volatile wiper
registers (AD3:AD0 = 00h, 01h, 06h, and 07h).
2: This command sequence does not need to terminate (using the Stop bit) and can
change to any other desired command sequence (INCR, Read, or Write).
FIGURE 7-8:
DS22265A-page 70
I2C Decrement Command Sequence.
© 2010 Microchip Technology Inc.
MCP444X/446X
7.8
Modify Write Protect or WiperLock
Technology (High Voltage)
Enable and Disable
These commands are special cases of the High
Voltage Decrement Wiper and the High Voltage
Increment Wiper commands to the nonvolatile
memory locations 02h, 03h, 08h, 09h, and 0Fh. This
command is used to enable or disable either the
software Write Protect, wiper 0 WiperLock Technology,
wiper 1 WiperLock Technology, wiper 2 WiperLock
Technology, or wiper 3 WiperLock Technology. Table 76 shows the memory addresses, the High Voltage
command and the result of those commands on the
nonvolatile WP, WL0, or WL1 bits.
TABLE 7-6:
7.8.1
SINGLE MODIFY (ENABLE OR
DISABLE) WRITE PROTECT OR
WIPERLOCK TECHNOLOGY (HIGH
VOLTAGE)
Figure 7-9 (Disable) and Figure 7-10 (Enable) show
the formats for a single Modify Write Protect or
Wiper-Lock Technology command.
A Modify Write Protect or WiperLock Technology
Command will only start an EEPROM write cycle (twc)
after a properly formatted Command has been
received and the Stop condition occurs.
During an EEPROM write cycle, only serial commands
to Volatile memory (addresses 00h, 01h, 04h, and 05h)
are accepted. All other serial commands are ignored
until the EEPROM write cycle (twc) completes. This
allows the Host Controller to operate on the Volatile
Wiper registers and the TCON register, and to Read
the Status Register. The EEWA bit in the Status register
indicates the status of an EEPROM Write Cycle.
ADDRESS MAP TO MODIFY WRITE PROTECT AND WIPERLOCK TECHNOLOGY
Commands and Results
Memory
Address
High Voltage Decrement Wiper
High Voltage Increment Wiper
00h
Wiper 0 register is decremented
Wiper 0 register is incremented
01h
Wiper 1 register is decremented
Wiper 1 register is incremented
02h
WL0 is enabled
WL0 is disabled
03h
WL1 is enabled
WL1 is disabled
TCON0 register not changed
TCON0 register not changed
STATUS register not changed
STATUS register not changed
06h
Wiper 2 register is decremented
Wiper 2 register is incremented
07h
Wiper 3 register is decremented
Wiper 3 register is incremented
08h
WL2 is enabled
WL2 is disabled
09h
WL3 is enabled
WL3 is disabled
TCON1 register not changed
TCON1 register not changed
Reserved
Reserved
WP is enabled
WP is disabled
04h (1)
05h
0Ah
(1)
(1)
0Bh - 0Eh (1)
0Fh
Note 1:
Reserved addresses: Increment or Decrement commands are invalid for these addresses.
© 2010 Microchip Technology Inc.
DS22265A-page 71
MCP444X/446X
Write bit
Variable
Address
Fixed
Address
S 0 1
0
1
1 A1 A0 0
A
Device
Memory
Address
AD AD AD AD
3 2 1 0 0
FIGURE 7-9:
Disable Command Sequence.
Write bit
Variable
Address
Fixed
Address
S 0
1 0
1
1 A1 A0 0 A
Device
Memory
Address
DS22265A-page 72
Command (Decrement)
AD AD AD AD
3 2 1 0 1
Control Byte
FIGURE 7-10:
1 X X A P
Disable Command
Control Byte
I2C
Command (Increment)
0 X X A P
Enable Command
2
I C Enable Command Sequence.
© 2010 Microchip Technology Inc.
MCP444X/446X
8.0
APPLICATIONS EXAMPLES
Nonvolatile digital potentiometers have a multitude of
practical uses in modern electronic circuits. The most
popular uses include precision calibration of set point
thresholds, sensor trimming, LCD bias trimming, audio
attenuation, adjustable power supplies, motor control
overcurrent trip setting, adjustable gain amplifiers and
offset trimming. The MCP44XX devices can be used to
replace the common mechanical trim pot in
applications where the operating and terminal voltages
are within CMOS process limitations (VDD = 2.7V to
5.5V).
8.1
Techniques to Force the HVC/A0
Pin to VIHH
The circuit in Figure 8-1 shows a method using the
TC1240A doubling charge pump. When the SHDN pin
is high, the TC1240A is off, and the level on the HVC/
A0 pin is controlled by the PIC® microcontrollers
(MCUs) IO2 pin.
When the SHDN pin is low, the TC1240A is on and the
VOUT voltage is 2 * VDD. The resistor R1 allows the
HVC/A0 pin to go higher than the voltage such that the
PIC MCU’s IO2 pin “clamps” at approximately VDD.
PIC MCU
TC1240A
C+
VIN
CSHDN
IO2
R1
GP0 is a general purpose I/O pin, while GP2 can either
be a general purpose I/O pin or it can output the internal
clock.
For the serial commands, configure the GP2 pin as an
input (high impedance). The output state of the GP0 pin
will determine the voltage on the HVC/A0 pin (VIL or
VIH).
For high-voltage serial commands, force the GP0
output pin to output a high level (VOH) and configure the
GP2 pin to output the internal clock. This will form a
charge pump and increase the voltage on the CS pin
(when the system voltage is approximately 5V).
PIC10F206
R1
GP0
MCP4XXX
C1
VOUT
IO1
The circuit in Figure 8-2 shows the method used on the
MCP402X Nonvolatile Digital Potentiometer Evaluation
Board (Part Number: MCP402XEV). This method
requires that the system voltage be approximately 5V.
This ensures that when the PIC10F206 enters a brownout condition, there is an insufficient voltage level on
the HVC/A0 pin to change the stored value of the wiper.
The MCP402X Nonvolatile Digital Potentiometer Evaluation Board User’s Guide (DS51546) contains a
complete schematic.
GP2
HVC/A0
C1
MCP4XXX
HVC/A0
C2
C2
FIGURE 8-2:
MCP4XXX Nonvolatile
Digital Potentiometer Evaluation Board
(MCP402XEV) implementation to generate the
VIHH voltage.
FIGURE 8-1:
Using the TC1240A to
Generate the VIHH Voltage.
© 2010 Microchip Technology Inc.
DS22265A-page 73
MCP444X/446X
8.2
Using Shutdown Modes
Figure 8-3 shows a possible application circuit where
the independent terminals could be used.
Disconnecting the wiper allows the transistor input to
be taken to the Bias voltage level (disconnecting A and
or B may be desired to reduce system current).
Disconnecting Terminal A modifies the transistor input
by the RBW rheostat value to the Common B.
Disconnecting Terminal B modifies the transistor input
by the RAW rheostat value to the Common A. The
Common A and Common B connections could be
connected to VDD and VSS.
8.3
Software Reset Sequence
Note:
This technique is documented in AN1028.
At times, it may become necessary to perform a
Software Reset Sequence to ensure the MCP44XX
device is in a correct and known I2C Interface state.
This technique only resets the I2C state machine.
This is useful if the MCP44XX device powers up in an
incorrect state (due to excessive bus noise, etc), or if
the Master Device is reset during communication.
Figure 8-4 shows the communication sequence to
software reset the device.
S
‘1’
‘1’
‘1’
‘1’
‘1’
‘1’
‘1’
‘1’
S
P
Common A
Nine bits of ‘1’
Start bit
Start
bit
Input
A
Stop bit
FIGURE 8-4:
Format.
To base
of Transistor
(or Amplifier)
W
B
Input
Common B
Balance
Bias
FIGURE 8-3:
Example Application Circuit
using Terminal Disconnects.
Software Reset Sequence
The 1st Start bit will cause the device to reset from a
state in which it is expecting to receive data from the
Master Device. In this mode, the device is monitoring
the data bus in Receive mode and can detect the Start
bit forces an internal Reset.
The nine bits of ‘1’ are used to force a Reset of those
devices that could not be reset by the previous Start bit.
This occurs only if the MCP44XX is driving an A bit on
the I2C bus, or is in output mode (from a Read
command) and is driving a data bit of ‘0’ onto the I2C
bus. In both of these cases, the previous Start bit could
not be generated due to the MCP44XX holding the bus
low. By sending out nine ‘1’ bits, it is ensured that the
device will see a A bit (the Master Device does not drive
the I2C bus low to acknowledge the data sent by the
MCP44XX), which also forces the MCP44XX to reset.
The 2nd Start bit is sent to address the rare possibility
of an erroneous write. This could occur if the Master
Device was reset while sending a Write command to
the MCP44XX, AND then as the Master Device returns
to normal operation and issues a Start condition while
the MCP44XX is issuing an Acknowledge. In this case,
if the 2nd Start bit is not sent (and the Stop bit was sent)
the MCP44XX could initiate a write cycle.
Note:
The potential for this erroneous write
ONLY occurs if the Master Device is reset
while sending a Write command to the
MCP44XX.
The Stop bit terminates the current I2C bus activity. The
MCP44XX waits to detect the next Start condition.
This sequence does not effect any other I2C devices
which may be on the bus, as they should disregard this
as an invalid command.
DS22265A-page 74
© 2010 Microchip Technology Inc.
MCP444X/446X
8.4
Figure 8-5 shows two I2C bus configurations. In many
cases, the single I2C bus configuration will be
adequate. For applications that do not want all the
MCP44XX devices to do General Call support or have
a conflict with General Call commands, the multiple I2C
bus configuration would be used.
Using the General Call Command
The use of the General Call Address Increment,
Decrement, or Write commands is analogous to the
“Load” feature (LDAC pin) on some DACs (such as the
MCP4921). This allows all the devices to “Update” the
output level “at the same time”.
For some applications, the ability to update the wiper
values “at the same time” may be a requirement, since
they delay from writing to one wiper value and then the
next may cause application issues. A possible example
would be a “tuned” circuit that uses several MCP44XX
in rheostat configuration. As the system condition
changes (temperature, load, etc.) these devices need
to be changed (incremented/decremented) to adjust for
the system change. These changes will either be in the
same direction or in opposite directions. With the
Potentiometer device, the customer can either select
the PxB terminals (same direction) or the PxA
terminal(s) (opposite direction).
Single I2C Bus Configuration
Device 1
Host
Controller
Device 4
Device 2
Multiple I2C Bus Configuration
Device 1a
Device 3a
Device na
Host
Bus a
Controller
Figure 8-6 shows that the update of six devices takes
6*TI2CDLY time in “normal” operation, but only
1*TI2CDLY time in “General Call” operation.
Note:
Device n
Device 3
Device 4a
Device 2a
The application system may need to
partition the I2C bus into multiple busses to
ensure that the MCP44XX General Call
commands do not conflict with the General
Call commands that the other I2C devices
may have defined. Also if only a portion of
the MCP44XX devices are to require this
synchronous operation, then the devices
that should not receive these commands
should be on the second I2C bus.
Device 1b
Device 3b
Device nb
Bus b
Device 4b
Device 2b
Device 1n
Device 3n
Device nn
Bus n
Device 2n
FIGURE 8-5:
Configurations.
Device 4n
Typical Application I2C Bus
Normal Operation
INC
POT01
TI2CDLY
INC
POT02
TI2CDLY
INC
POT03
TI2CDLY
INC
POT04
TI2CDLY
INC
POT05
TI2CDLY
INC
POT06
TI2CDLY
General Call Operation
INC
POTs 01-06
TI2CDLY
INC
POTs 01-06
TI2CDLY
INC
POTs 01-06
TI2CDLY
INC
POTs 01-06
TI2CDLY
INC
POTs 01-06
TI2CDLY
INC
POTs 01-06
TI2CDLY
TI2CDLY = Time from one I2C command completed to completing the next I2C command.
FIGURE 8-6:
Updates.
Example Comparison of “Normal Operation” vs. “General Call Operation” Wiper
© 2010 Microchip Technology Inc.
DS22265A-page 75
MCP444X/446X
8.5
Implementing Log Steps with a
Linear Digital Potentiometer
In audio volume control applications, the use of
logarithmic steps is desirable since the human ear
hears in a logarithmic manner. The use of a linear
potentiometer can approximate a log potentiometer,
but with fewer steps. An 8-bit potentiometer can
achieve fourteen 3 dB log steps plus a 100% (0 dB)
and a mute setting.
Figure 8-7 shows a block diagram of one of the
MCP44x1 resistor networks being used to attenuate an
input signal. In this case, the attenuation will be ground
referenced. Terminal B can be connected to a common
mode voltage, but the voltages on the A, B and Wiper
terminals must not exceed the MCP44x1’s VDD/VSS
voltage limits.
MCP44X1
P0A
P0W
EQUATION 8-1:
dB CALCULATIONS
(VOLTAGE)
L = 20 * log10 (VOUT / VIN)
dB
-3
-2
-1
EQUATION 8-2:
VOUT / VIN Ratio
0.70795
0.79433
0.89125
dB CALCULATIONS
(RESISTANCE) - CASE 1
Terminal B connected to Ground (see Figure 8-7)
L = 20 * log10 (RBW / RAB)
EQUATION 8-3:
dB CALCULATIONS
(RESISTANCE) - CASE 2
Terminal B through RB2GND to Ground
L = 20 * log10 ( (RBW + RB2GND) / (RAB + RB2GND) )
P0B
FIGURE 8-7:
Signal Attenuation Block
Diagram - Ground Referenced.
Equation 8-1 shows the equation to calculate voltage
dB gain ratios for the digital potentiometer, while
Equation 8-2 shows the equation to calculate
resistance dB gain ratios. These two equations assume
that the B terminal is connected to ground.
If terminal B is not directly resistively connected to
ground, then this terminal B to ground resistance
(RB2GND) must be included into the calculation.
Equation 8-3 shows this equation.
DS22265A-page 76
Table 8-1 shows the codes that can be used for 8-bit
digital potentiometers to implement the log attenuation.
The table shows the wiper codes for -3 dB, -2 dB, and
-1 dB attenuation steps. This table also shows the
calculated attenuation based on the wiper code’s linear
step. Calculated attenuation values less than the
desired attenuation are shown with red text. At lower
wiper code values, the attenuation may skip a step, if
this occurs the next attenuation value is colored
magenta to highlight that a skip occurred. For example,
in the -3 dB column the -48 dB value is highlighted
since the -45 dB step could not be implemented (there
are no wiper codes between 2 and 1).
© 2010 Microchip Technology Inc.
MCP444X/446X
TABLE 8-1:
LINEAR TO LOG ATTENUATION FOR 8-BIT DIGITAL POTENTIOMETERS
-3 dB Steps
# of
Steps
-2 dB Steps
-1 dB Steps
Calculated
Calculated
Calculated
Desired
Wiper
Desired
Wiper
Desired
Wiper
Attenuation
Attenuation
Attenuation
Attenuation Code
Attenuation Code
Attenuation Code
(1)
(1)
(1)
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
Note 1:
0 dB
-3 dB
-6 dB
-9dB
-12 dB
-15 dB
-18 dB
-21 dB
-24 dB
-27 dB
-30 dB
-33 dB
-36 dB
-39 dB
-42 dB
-48 dB
Mute
256
181
128
91
64
46
32
23
16
11
8
6
4
3
2
1
0
0 dB
256
0 dB
-1 dB
228 -1.006 dB
-2 dB
203 -2.015 dB
-3 dB
181 -3.011 dB
-4 dB
162 -3.975 dB
-5 dB
144 -4.998 dB
-6 dB
128 -6.021 dB
-7 dB
114 -7.027 dB
-8 dB
102 -7.993 dB
-9 dB
91 -8.984 dB
-10 dB
81 -9.995 dB
-11 dB
72 -11.018 dB
-12 dB
64 -12.041 dB
-13 dB
57 -13.047 dB
-14 dB
51 -14.013 dB
-15 dB
46 - 14.910 dB
-16 dB
41 -15.909 dB
-17 dB
36 -17.039 dB
-18 dB
32 -18.062 dB
-19 dB
29 -18.917 dB
-20 dB
26 -19.865 dB
-21 dB
23 - 20.930 dB
-22 dB
20 -22.144 dB
-23 dB
18 -23.059 dB
-24 dB
16 -24.082 dB
-25 dB
14 -25.242 dB
-26 dB
13 -25.886 dB
-27dB
11 -27.337 dB
-28 dB
10 -28.165 dB
-29 dB
9 -29.080 dB
-30 dB
8 -30.103 dB
-31 dB
7 -31.263 dB
-33 dB
6 -32.602 dB
-34 dB
5 -34.185 dB
-36 dB
4 -36.124 dB
-39 dB
3 -38.622 dB
-42 dB
2 -42.144 dB
-48 dB
1 -48.165 dB
Mute
0
Mute
Attenuation values do not include errors from Digital Potentiometer errors, such as Full Scale Error or Zero
Scale Error.
© 2010 Microchip Technology Inc.
0 dB
-3.011 dB
-6.021 dB
-8.984 dB
-12.041 dB
-14.910 dB
-18.062 dB
-20.930 dB
-24.082 dB
-27.337 dB
-30.103 dB
-32.602 dB
-36.124 dB
-38.622 dB
-42.144 dB
-48.165 dB
Mute
0 dB
-2 dB
-4 dB
-6 dB
-8 dB
-10 dB
-12 dB
-14 dB
-16 dB
-18 dB
-20 dB
-22 dB
-24 dB
-26 dB
-28 dB
-30 dB
-32 dB
-34 dB
-36 dB
-38 dB
-42 dB
-48 dB
Mute
256
203
162
128
102
81
64
51
41
32
26
20
16
13
10
8
6
5
4
3
2
1
0
0 dB
-2.015 dB
-3.975 dB
-6.021 dB
-7.993 dB
-9.995 dB
-12.041 dB
-14.013 dB
-15.909 dB
-18.062 dB
-19.865 dB
-22.144 dB
-24.082 dB
-25.886 dB
-28.165 dB
-30.103 dB
-32.602 dB
-34.185 dB
-36.124 dB
-38.622 dB
-42.144 dB
-48.165 dB
Mute
DS22265A-page 77
MCP444X/446X
8.6
8.6.2
Design Considerations
In the design of a system with the MCP44XX devices,
the following considerations should be taken into
account:
LAYOUT CONSIDERATIONS
Several layout considerations may be applicable to
your application. These may include:
• Power Supply Considerations
• Layout Considerations
• Noise
• Footprint Compatibility
• PCB Area Requirements
8.6.1
8.6.2.1
POWER SUPPLY
CONSIDERATIONS
The typical application will require a bypass capacitor
in order to filter high-frequency noise, which can be
induced onto the power supply's traces. The bypass
capacitor helps to minimize the effect of these noise
sources on signal integrity. Figure 8-8 illustrates an
appropriate bypass strategy.
In this example, the recommended bypass capacitor
value is 0.1 µF. This capacitor should be placed as
close (within 4 mm) to the device power pin (VDD) as
possible.
The power source supplying these devices should be
as clean as possible. If the application circuit has
separate digital and analog power supplies, VDD and
VSS should reside on the analog plane.
VDD
Noise
Inductively-coupled AC transients and digital switching
noise can degrade the input and output signal integrity,
potentially masking the MCP44XX’s performance.
Careful board layout minimizes these effects and
increases the Signal-to-Noise Ratio (SNR). Multi-layer
boards utilizing a low-inductance ground plane,
isolated inputs, isolated outputs and proper decoupling
are critical to achieving the performance that the silicon
is capable of providing. Particularly harsh
environments may require shielding of critical signals.
If low noise is desired, breadboards and wire-wrapped
boards are not recommended.
8.6.2.2
Footprint Compatibility
The specification of the MCP44XX pinouts was done to
allow systems to be designed to easily support the use
of either the dual (MCP46XX) or quad (MCP44XX)
device.
Figure 8-9 shows how the dual pinout devices fit on the
quad device footprint. For the Rheostat devices, the
dual device is in the MSOP package, so the footprints
would need to be offset from each other.
0.1 µF
VDD
W
B
MCP444X/446X
A
VSS
FIGURE 8-8:
Connections.
SCL
SDA
HVC/A0
A1
PICTM Microcontroller
MCP44X1 Quad Potentiometers
0.1 µF
VSS
Typical Microcontroller
P3A
P3W
P3B
HVC/A0
SCL
SDA
VSS
P1B
P1W
P1A
1
2
3
4
5
6
7
8
9
10
20
19
18
17
16
15
14
12
12
11
P2A
P2W
P2B
VDD
A1
RESET
WP
P0B
P0W
P0A
MCP42X1 Pinout (1)
TSSOP
MCP44X2 Quad Rheostat
P3W
P3B
HVC/A0
SCL
SDA
VSS
P1B
1
2
3
4
5
6
7
14
13
12
11
10
9
8
P2W
P2B
VDD
A1
P0B
P0W
P1W
MCP42X2 Pinout
TSSOP
Note 1: Pin 15 (RESET) is the Address A2 (A2)
pin on the MCP46x1 device.
FIGURE 8-9:
Quad Pinout (TSSOP
Package) vs. Dual Pinout.
DS22265A-page 78
© 2010 Microchip Technology Inc.
MCP444X/446X
MCP44X1
In some applications, PCB area is a criteria for device
selection. Table 8-2 shows the package dimensions
and area for the different package options. The table
also shows the relative area factor compared to the
smallest area. For space critical applications, the QFN
package would be the suggested package.
PACKAGE FOOTPRINT (1)
TABLE 8-2:
Package
Pins
MCP46X1
PCB Area Requirements
Package Footprint
Dimensions
(mm)
Type
Code
X
Rheostat Devices
MCP46X2
MCP44X2
14
TSSOP
ST
5.10
QFN
ML
4.00
20
TSSOP
ST
6.60
Note 1: Does not include
pattern dimensions.
8.6.3
FIGURE 8-10:
Dual Devices.
Layout to Support Quad and
Y
Relative Area
Potentiometers Devices
8.6.2.3
Area (mm2)
Figure 8-10 shows possible layout implementations for
an application to support the quad and dual options on
the same PCB.
6.40 32.64 2.04
4.00 16.00
1
6.40 42.24 2.64
recommended land
RESISTOR TEMPCO
Characterization curves of the resistor temperature
coefficient (Tempco) are shown in Figure 2-10,
Figure 2-26, Figure 2-41, and Figure 2-56.
These curves show that the resistor network is
designed to correct for the change in resistance as
temperature increases. This technique reduces the
end to end change is RAB resistance.
8.6.4
HIGH VOLTAGE TOLERANT PINS
High Voltage support (VIHH) on the Serial Interface pins
supports two features. These are:
• In-Circuit Accommodation of split rail applications
and power supply sync issues
• User configuration of the Nonvolatile EEPROM,
Write Protect, and WiperLock feature
Note:
© 2010 Microchip Technology Inc.
In many applications, the High Voltage will
only be present at the manufacturing
stage so as to “lock” the Nonvolatile wiper
value (after calibration) and the contents
of the EEPROM. This ensures that since
High Voltage is not present under normal
operating conditions, these values can not
be modified.
DS22265A-page 79
MCP444X/446X
9.0
DEVELOPMENT SUPPORT
9.1
Development Tools
9.2
Technical Documentation
Several additional technical documents are available to
assist you in your design and development. These
technical documents include Application Notes,
Technical Briefs, and Design Guides. Table 9-2 shows
some of these documents.
Several development tools are available to assist in
your design and evaluation of the MCP44XX devices.
The currently available tools are shown in Table 9-1.
These boards may be purchased directly from the
Microchip web site at www.microchip.com.
TABLE 9-1:
DEVELOPMENT TOOLS
Board Name
Part #
Supported Devices
20-pin TSSOP and SSOP Evaluation Board
TSSOP20EV
MCP44XX
MCP46XX Digital Potentiometer PICtail Plus Demo MCP46XXDM-PTPLS
Board (1, 2)
MCP46XX
MCP46XX Digital Potentiometer Evaluation Board (2) MCP46XXEV
MCP46X1
Note 1: Requires a PICDEM Demo board. See the User’s Guide for additional information and requirements.
2: Requires a PICkit Serial Analyzer. See the User’s Guide for additional information and requirements.
TABLE 9-2:
TECHNICAL DOCUMENTATION
Application
Note Number
Title
Literature #
AN1316
Using Digital Potentiometers for Programmable Amplifier Gain
DS01316
AN1080
Understanding Digital Potentiometers Resistor Variations
DS01080
AN737
Using Digital Potentiometers to Design Low-Pass Adjustable Filters
DS00737
AN692
Using a Digital Potentiometer to Optimize a Precision Single Supply Photo Detect
DS00692
AN691
Optimizing the Digital Potentiometer in Precision Circuits
DS00691
AN219
Comparing Digital Potentiometers to Mechanical Potentiometers
DS00219
—
Digital Potentiometer Design Guide
DS22017
—
Signal Chain Design Guide
DS21825
DS22265A-page 80
© 2010 Microchip Technology Inc.
MCP444X/446X
10.0
PACKAGING INFORMATION
10.1
Package Marking Information
14-Lead TSSOP
Example
4462502E
XXXXXXXX
1035
YYWW
NNN
256
20-Lead QFN (4x4)
4461
502EML
3 1035
e
^^
256
XXXXX
XXXXXX
XXXXXX
YYWWNNN
Example
20-Lead TSSOP
XXXXXXXX
4461502
XXXXX NNN
YYWW
EST ^^
e3 256
1035
Legend: XX...X
Y
YY
WW
NNN
e3
*
Note:
Example
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.
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.
© 2010 Microchip Technology Inc.
DS22265A-page 81
MCP444X/446X
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
DS22265A-page 82
© 2010 Microchip Technology Inc.
MCP444X/446X
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
© 2010 Microchip Technology Inc.
DS22265A-page 83
MCP444X/446X
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
DS22265A-page 84
© 2010 Microchip Technology Inc.
MCP444X/446X
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DS22265A-page 85
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© 2010 Microchip Technology Inc.
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© 2010 Microchip Technology Inc.
DS22265A-page 87
MCP444X/446X
Note:
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
DS22265A-page 88
© 2010 Microchip Technology Inc.
MCP444X/446X
APPENDIX A:
REVISION HISTORY
Revision A (September 2010)
• Original Release of this Document.
© 2010 Microchip Technology Inc.
DS22265A-page 89
MCP444X/446X
NOTES:
DS22265A-page 90
© 2010 Microchip Technology Inc.
MCP444X/446X
CHARACTERIZATION
DATA ANALYSIS
Some designers may want to understand the device
operational characteristics outside of the specified
operating conditions of the device.
Applications where the knowledge of the resistor
network characteristics could be useful include battery
powered devices and applications that experience
brown-out conditions.
In battery applications, the application voltage decays
over time until new batteries are installed. As the
voltage decays, the system will continue to operate. At
some voltage level, the application will be below its
specified operating voltage range. This is dependent
on the individual components used in the design. It is
still useful to understand the device characteristics to
expect when this low-voltage range is encountered.
Unlike a microcontroller, which can use an external
supervisor device to force the controller into the Reset
state, a digital potentiometer’s resistance characteristic
is not specified. But understanding the operational
characteristics can be important in the design of the
applications circuit for this low-voltage condition.
Other
application
system
scenarios
where
understanding the low-voltage characteristics of the
resistor network could be important is for system brown
out conditions.
For the MCP444X/446X devices, the analog operation
is specified at a minimum of 2.7V. Device testing has
Terminal A connected to the device VDD (for the
potentiometer configuration only) and Terminal B
connected to VSS.
B.1
Low-Voltage Operation
This appendix gives an overview of CMOS
semiconductor characteristics at lower voltages. This is
important so that the 1.8V resistor network
characterization graphs of the MCP444X/446X devices
can be better understood.
For this discussion, we will use the 5 kΩ device data.
This data was chosen since the variations of wiper
resistance have much greater implications for devices
with smaller RAB resistances.
Figure B-1 shows the worst case RBW error from the
average RBW as a percentage, while Figure B-2 shows
the RBW resistance versus the wiper code graph.
Non-linear behavior occurs at approximately wiper
code 160. This is better shown in Figure B-2, where the
RBW resistance changes from a linear slope. This
change is due to the change in the wiper resistance.
2.00%
1.00%
0.00%
-1.00%
Error %
APPENDIX B:
-2.00%
-3.00%
-4.00%
-40C
+25C
+85C
+125C
-5.00%
-6.00%
-7.00%
0
32
64
96
128
160
192
224
256
Wiper Code
FIGURE B-1:
1.8V Worst Case RBW Error
from Average RBW (RBW0-RBW3) vs. Wiper Code
and Temperature (VDD = 1.8V, IW = 190 µA).
7000
Resistance ()
6000
5000
4000
3000
-40C
+25C
+85C
+125C
2000
1000
0
0
32
64
96
128
160
Wiper Code
192
224
256
FIGURE B-2:
RBW vs. Wiper Code And
Temperature (VDD = 1.8V, IW = 190 µA).
© 2010 Microchip Technology Inc.
DS22265A-page 91
MCP444X/446X
Figure B-3 and Figure B-4 show the wiper resistance
for VDD voltages of 5.5, 3.0, 1.8 Volts. These graphs
show that as the resistor ladder wiper node voltage
(VWCn) approaches the VDD/2 voltage, the wiper
resistance increases. These graphs also show the
different resistance characteristics of the NMOS and
PMOS transistors that make up the wiper switch. This
is demonstrated by the wiper code resistance curve,
which does not mirror itself around the mid-scale code
(wiper code = 128).
So why are the RW graphs showing the maximum
resistance at about mid-scale (wiper code = 128) and
the RBW graphs showing the issue at code 160?
This requires understanding low-voltage transistor
characteristics as well as how the data was measured.
220
200
Resistance ()
180
-40C @ 3.0V
+25C @ 3.0V
+85C @ 3.0V
+125C @ 3.0V
-40C @5.5V
+25C @ 5.5V
+85C @ 5.5V
+125C @ 5.5V
160
floating
VA
A
120
VW
W
IW
B
140
VB
RBW = VW/IW
RW = (VW-VA)/IW
100
80
FIGURE B-5:
60
40
20
0
64
128
192
256
Wiper Code
FIGURE B-3:
Wiper Resistance (RW) vs.
Wiper Code and Temperature
(VDD = 5.5V, IW = 900 µA; VDD = 3.0V,
IW = 480 µA).
2020
+25C @ 1.8V
1520
+125C @ 1.8V
1020
520
20
0
64
128
192
256
Wiper Code
FIGURE B-4:
Wiper Resistance (RW) vs.
Wiper Code and Temperature
(VDD = 1.8V, IW = 260 µA).
DS22265A-page 92
RBW and RW Measurement.
Figure B-6 shows a block diagram of the resistor
network where the RAB resistor is a series of 256 RS
resistors. These resistors are polysilicon devices. Each
wiper switch is an analog switch made up of an NMOS
and PMOS transistor. A more detailed figure of the
wiper switch is shown in Figure B-7. The wiper
resistance is influenced by the voltage on the wiper
switches nodes (VG, VW and VWCn). Temperature also
influences the characteristics of the wiper switch, see
Figure B-4.
The NMOS transistor and PMOS transistor have
different characteristics. These characteristics, as well
as the wiper switch node voltages, determine the RW
resistance at each wiper code. The variation of each
wiper switch’s characteristics in the resistor network is
greater then the variation of the RS resistors.
-40C @ 1.8V
+85C @ 1.8V
Resistance ()
The method in which the data was collected is
important to understand. Figure B-5 shows the
technique that was used to measure the RBW and RW
resistance. In this technique, Terminal A is floating and
Terminal B is connected to ground. A fixed current is
then forced into the wiper (IW) and the corresponding
wiper voltage (VW) is measured. Forcing a known
current through RBW (IW) and then measuring the
voltage difference between the wiper (VW) and
Terminal A (VA), the wiper resistance (RW) can be
calculated, see Figure B-5. Changes in IW current will
change the wiper voltage (VW). This may affect the
device’s wiper resistance (RW).
The voltage on the resistor network node (VWCn) is
dependent upon the wiper code selected and the
voltages applied to VA, VB and VW. The wiper switch VG
voltage to VW or VWCn voltage determines how strongly
the transistor is turned on. When the transistor is
weakly turned on, the wiper resistance RW will be high.
When the transistor is strongly turned on, the wiper
resistance (RW) will be in the typical range.
© 2010 Microchip Technology Inc.
MCP444X/446X
So looking at the wiper voltage (VW) for the
3.0V and 1.8V data gives the graphs in Figure B-8 and
Figure B-9. In the 1.8V graph, as the VW approaches
0.8V, the voltage increases nonlinearly. Since V = I * R,
and the current (IW) is constant, it means that the
device resistance increased nonlinearly at around
wiper code 160.
A
VA
RS
RW (1)
Nn-1
DVG
RW (1)
RS
Nn-2
RS
VWC(n-2)
RAB
Nn-3
1.2
1.0
NMOS
PMOS
RW (1)
VW
W
Wiper Voltage (V)
Nn
0.8
0.6
0.4
-40C
+25C
+85C
+125C
0.2
0.0
RS
RW
(1)
RW
(1)
N0
B
Note 1:
0
32
64
96 128 160
Wiper Code
192
224
256
FIGURE B-8:
Wiper Voltage (VW) vs.
Wiper Code (VDD = 3.0V, IW = 190 µA).
1.4
VB
1.2
The wiper resistance is dependent on
several factors including, wiper code,
device VDD, Terminal voltages (on A, B
and W), and temperature.
FIGURE B-6:
Diagram.
Resistor Network Block
Wiper Voltage (V)
N1
1.0
0.8
0.6
-40C
+25C
+85C
+125C
0.4
0.2
The characteristics of the wiper are determined by the
characteristics of the wiper switch at each of the
resistor networks tap points. Figure B-7 shows an
example of a wiper switch. As the device operational
voltage becomes lower, the characteristics of the wiper
switch change due to a lower voltage on the VG signal.
0.0
0
32
64
96
128 160
Wiper Code
192
224
256
FIGURE B-9:
Wiper Voltage (VW) vs.
Wiper Code (VDD = 1.8V, IW = 190 µA).
Figure B-7 shows an implementation of a wiper switch.
When the transistor is turned off, the switch resistance
is in the Giga Ωs. When the transistor is turned on, the
switch resistance is dependent on the VG, VW and
VWCn voltages. This resistance is referred to as RW.
RW (1)
VG (VDD/VSS)
“gate”
NMOS
NWC
VWCn
PMOS
Wiper
VW
“gate”
Note 1: Wiper Resistance (RW) depends on the
voltages at the wiper switch nodes
(VG, VW and VWCn).
FIGURE B-7:
Wiper Switch.
© 2010 Microchip Technology Inc.
DS22265A-page 93
MCP444X/446X
RW
RPMOS
140
RW
120
5.00E+09
100
4.00E+09
3.00E+09
80
NMOS
PMOS Theshold
Theshold
2.00E+09
60
40
1.00E+09
20
0.00E+00
0
0.0
0.6
1.2
1.8
VIN Voltage
2.4
3.0
FIGURE B-12:
NMOS and PMOS
Transistor Resistance (RNMOS, RPMOS) and
Wiper Resistance (RW) VS. VIN
(VDD = 1.8V).
300
NMOS
250
Resistance ()
VOUT
PMOS
“gate”
FIGURE B-10:
6.00E+09
VG (VDD/VSS)
“gate”
VIN
160
RNMOS
Wiper Resistance ()
7.00E+09
NMOS and PMOS Resistance
()
Using the simulation models of the NMOS and PMOS
devices for the MCP44XX analog switch (Figure B-10),
we plot the device resistance when the devices are
turned on. Figure B-11 and Figure B-12 show the
resistances of the NMOS and PMOS devices as the
VIN voltage is increased. The wiper resistance (RW) is
simply the parallel resistance on the NMOS and PMOS
devices (RW = RNMOS || RPMOS). Below the threshold
voltage for the NMOS ad PMOS devices, the
resistance becomes very large (Gigaohms). In the
transistors active region, the resistance is much lower.
For these graphs, the resistances are on different
scales. Figure B-13 and Figure B-14 only plot the
NMOS and PMOS device resistance for their active
region and the resulting wiper resistance. For these
graphs, all resistances are on the same scale.
Analog Switch.
200
RNMOS
RPMOS
150
100
RW
50
RW
2500
RNMOS
0
2.50E+10
2000
RPMOS
2.00E+10
1500
1.50E+10
1000
1.00E+10
NMOS
500
Theshold
PMOS
Theshold
5.00E+09
0.00E+00
0.0
Wiper Resistance ()
NMOS and PMOS Resistance
()
3.00E+10
0.3
0.6
0.9
1.2
VIN Voltage
1.5
1.2
1.8
VIN Voltage
2.4
3.0
FIGURE B-13:
NMOS and PMOS
Transistor Resistance (RNMOS, RPMOS) and
Wiper Resistance (RW) VS. VIN
(VDD = 3.0V).
0
0.0
0.6
5000
1.8
4500
Resistance ()
4000
FIGURE B-11:
NMOS and PMOS
Transistor Resistance (RNMOS, RPMOS) and
Wiper Resistance (RW) VS. VIN
(VDD = 3.0V).
3500
3000
RNMOS
2500
RPMOS
2000
RW
1500
1000
500
0
0.0
0.3
0.6
0.9
1.2
VIN Voltage
1.5
1.8
FIGURE B-14:
NMOS and PMOS
Transistor Resistance (RNMOS, RPMOS) and
Wiper Resistance (RW) VS. VIN
(VDD = 1.8V).
DS22265A-page 94
© 2010 Microchip Technology Inc.
MCP444X/446X
B.2
Optimizing Circuit Design for
Low-Voltage Characteristics
R1
The low-voltage nonlinear characteristics can be
minimized by application design. The section will show
two application circuits that can be used to control a
programmable reference voltage (VOUT).
A
In example implementation #1 (Figure B-15), we
window the digital potentiometer using resistors R1 and
R2. When the wiper code is at full scale, the VOUT
voltage will be ≥ 0.6 * VDD, and when the wiper code is
at zero scale the VOUT voltage will be ≤ 0.5 * VDD.
Remember that the digital potentiometers RAB variation
must be included. Table B-1 shows that the VOUT
voltage can be selected to be between 0.455 * VDD and
0.727 * VDD, which includes the desired range. With
respect to the voltages on the resistor network node, at
1.8V the VA voltage would range from 1.29V to 1.31V
while the VB voltage would range from 0.82V to 0.86V.
These voltages cause the wiper resistance to be in the
nonlinear region (see Figure B-12). In Potentiometer
mode, the variation of the wiper resistance is typically
not an issue, as shown by the INL/DNL graph
(Figure 2-7).
VW
W
Minimizing the low-voltage nonlinear characteristics is
done by keeping the voltages on the wiper switch
nodes at a voltage where either the NMOS or PMOS
transistor is turned on.
An example of this is if we are using a digital
potentiometer for a voltage reference (VOUT). Let’s say
that we want VOUT to range from 0.5 * VDD to 0.6 * VDD.
VA
B
VOUT
VB
R2
FIGURE B-15:
TABLE B-1:
Example Implementation #1.
EXAMPLE #1 VOLTAGE
CALCULATIONS
Variation
Min
Typ
Max
R1
12,000
12,000
12,000
R2
20,000
20,000
20,000
RAB
8,000
10,000
12,000
VOUT (@ FS) 0.714 VDD
VOUT (@ ZS) 0.476 VDD
0.70 VDD
0.727 VDD
0.50 VDD
0.455 VDD
VA
0.714 VDD
0.70 VDD
0.727 VDD
VB
0.476 VDD
0.50 VDD
0.455 VDD
Legend: FS – Full Scale, ZS – Zero Scale
In example implementation #2 (Figure B-16) we use
the digital potentiometer in Rheostat mode. The
resistor ladder uses resistors R1 and R2 with RBW at
the bottom of the ladder. When the wiper code is at full
scale, the VOUT voltage will be ≥ 0.6 * VDD and when
the wiper code is at full scale the VOUT voltage will be
≤ 0.5 * VDD. Remember that the digital potentiometers
RAB variation must be included. Table B-2 shows that
the VOUT voltage can be selected to be between 0.50 *
VDD and 0.687 * VDD, which includes the desired
range. With respect to the voltages on the resistor
network node, at 1.8V the VW voltage would range from
0.29V to 0.38V. These voltages cause the wiper
resistance to be in the linear region (see Figure B-12).
© 2010 Microchip Technology Inc.
DS22265A-page 95
MCP444X/446X
R1
VOUT
R2
A VA
W
B
FIGURE B-16:
TABLE B-2:
VW
VB
Example Implementation #2.
EXAMPLE #2 VOLTAGE
CALCULATIONS
Variation
Min
Typ
Max
R1
10,000
10,000
10,000
R2
10,000
10,000
10,000
RBW (max)
8,000
10,000
12,000
VOUT (@ FS) 0.667 VDD
VOUT(@ ZS) 0.50 VDD
0.643 VDD
0.687 VDD
0.50 VDD
0.50 VDD
VW (@ FS)
0.333 VDD
0.286 VDD
0.375 VDD
VW (@ ZS)
VSS
VSS
VSS
Legend: FS – Full Scale, ZS – Zero Scale
DS22265A-page 96
© 2010 Microchip Technology Inc.
MCP444X/446X
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
PART NO.
-XXX
X
/XX
Device
Resistance
Version
Temperature
Range
Package
Device
MCP4441:
MCP4441T:
MCP4442:
MCP4442T:
MCP4461:
MCP4461T:
MCP4462:
MCP4462T:
Quad Nonvolatile 7-bit Potentiometer
Quad Nonvolatile 7-bit Potentiometer
(Tape and Reel)
Quad Nonvolatile 7-bit Rheostat
Quad Nonvolatile 7-bit Rheostat
(Tape and Reel)
Quad Nonvolatile 8-bit Potentiometer
Quad Nonvolatile 8-bit Potentiometer
(Tape and Reel)
Quad Nonvolatile 8-bit Rheostat
Quad Nonvolatile 8-bit Rheostat
(Tape and Reel)
Resistance Version:
502
103
503
104
=
=
=
=
5 kΩ
10 kΩ
50 kΩ
100 kΩ
Temperature Range
E
= -40°C to +125°C (Extended)
Package
ST = Plastic Thin Shrink Small Outline (TSSOP),
14/20-lead
ML = Plastic Quad Flat No-lead (4x4 QFN), 20-lead
© 2010 Microchip Technology Inc.
Examples:
a)
b)
c)
d)
e)
f)
g)
h)
MCP4441-502E/XX:
MCP4441T-502E/XX:
MCP4441-103E/XX:
MCP4441T-103E/XX:
MCP4441-503E/XX:
MCP4441T-503E/XX:
MCP4441-104E/XX:
MCP4441T-104E/XX:
5 kΩ, 20-LD Device
T/R, 5 kΩ, 20-LD Device
10 kΩ, 20-LD Device
T/R, 10 kΩ, 20-LD Device
50 kΩ, 20-LD Device
T/R, 50 kΩ, 20-LD Device
100 kΩ, 20-LD Device
T/R, 100 kΩ,
20-LD Device
a)
b)
c)
d)
e)
f)
g)
h)
MCP4442-502E/XX:
MCP4442T-502E/XX:
MCP4442-103E/XX:
MCP4442T-103E/XX:
MCP4442-503E/XX:
MCP4442T-503E/XX:
MCP4442-104E/XX:
MCP4442T-104E/XX:
5 kΩ, 14-LD Device
T/R, 5 kΩ, 14-LD Device
10 kΩ, 14-LD Device
T/R, 10 kΩ, 14-LD Device
50 kΩ, 8LD Device
T/R, 50 kΩ, 14-LD Device
100 kΩ, 14-LD Device
T/R, 100 kΩ,
14-LD Device
a)
b)
c)
d)
e)
f)
g)
h)
MCP4461-502E/XX:
MCP4461T-502E/XX:
MCP4461-103E/XX:
MCP4461T-103E/XX:
MCP4461-503E/XX:
MCP4461T-503E/XX:
MCP4461-104E/XX:
MCP4461T-104E/XX:
5 kΩ, 20-LD Device
T/R, 5 kΩ, 20-LD Device
10 kΩ, 20-LD Device
T/R, 10 kΩ, 20-LD Device
50 kΩ, 20-LD Device
T/R, 50 kΩ, 20-LD Device
100 kΩ, 20-LD Device
T/R, 100 kΩ,
20-LD Device
a)
b)
c)
d)
e)
f)
g)
h)
MCP4462-502E/XX:
MCP4462T-502E/XX:
MCP4462-103E/XX:
MCP4462T-103E/XX:
MCP4462-503E/XX:
MCP4462T-503E/XX:
MCP4462-104E/XX:
MCP4462T-104E/XX:
5 kΩ, 14-LD Device
T/R, 5 kΩ, 14-LD Device
10 kΩ, 14-LD Device
T/R, 10 kΩ, 14-LD Device
50 kΩ, 14-LD Device
T/R, 50 kΩ, 14-LD Device
100 kΩ, 14-LD Device
T/R, 100 kΩ,
14-LD Device
XX
= ST for 14/20-lead TSSOP
= ML for 20-lead QFN
DS22265A-page 97
MCP444X/446X
NOTES:
DS22265A-page 98
© 2010 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.
Trademarks
The Microchip name and logo, the Microchip logo, dsPIC,
KEELOQ, KEELOQ logo, MPLAB, PIC, PICmicro, PICSTART,
PIC32 logo, rfPIC and UNI/O are registered trademarks of
Microchip Technology Incorporated in the U.S.A. and other
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FilterLab, Hampshire, HI-TECH C, Linear Active Thermistor,
MXDEV, MXLAB, SEEVAL and The Embedded Control
Solutions Company are registered trademarks of Microchip
Technology Incorporated in the U.S.A.
Analog-for-the-Digital Age, Application Maestro, CodeGuard,
dsPICDEM, dsPICDEM.net, dsPICworks, dsSPEAK, ECAN,
ECONOMONITOR, FanSense, HI-TIDE, In-Circuit Serial
Programming, ICSP, Mindi, MiWi, MPASM, MPLAB Certified
logo, MPLIB, MPLINK, mTouch, Octopus, Omniscient Code
Generation, PICC, PICC-18, PICDEM, PICDEM.net, PICkit,
PICtail, REAL ICE, rfLAB, Select Mode, Total Endurance,
TSHARC, UniWinDriver, WiperLock 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.
All other trademarks mentioned herein are property of their
respective companies.
© 2010, Microchip Technology Incorporated, Printed in the
U.S.A., All Rights Reserved.
Printed on recycled paper.
ISBN: 978-1-60932-533-6
Microchip received ISO/TS-16949:2002 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.
© 2010 Microchip Technology Inc.
DS22265A-page 99
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DS22265A-page 100
© 2010 Microchip Technology Inc.