D ts e t
aa h e
R c e t r lc r nc
o h se Ee to is
Ma u a t r dCo o e t
n fc u e
mp n n s
R c e tr b a d d c mp n ns ae
o h se rn e
o oet r
ma ua trd u ig ete dewaes
n fcue sn i r i/ fr
h
p rh s d f m te oiia s p l r
uc a e r
o h r n l u pi s
g
e
o R c e tr waes rce td f m
r o h se
fr e rae r
o
te oiia I. Al rce t n ae
h
r nl P
g
l e rai s r
o
d n wi tea p o a o teOC
o e t h p rv l f h
h
M.
P r aetse u igoiia fcoy
at r e td sn r n la tr
s
g
ts p o rmso R c e tr e eo e
e t rga
r o h se d v lp d
ts s lt n t g aa te p o u t
e t oui s o u rne
o
rd c
me t o e c e teOC d t s e t
es r x e d h
M aa h e.
Qu l yOv riw
ai
t
e ve
• IO- 0 1
S 90
•A 92 cr ct n
S 1 0 et ai
i
o
• Qu l e Ma ua trr Ls (
ai d
n fcues it QML MI- R -
) LP F
385
53
•C a sQ Mitr
ls
lay
i
•C a sVS a eL v l
ls
p c ee
• Qu l e S p l r Ls o D sr uos( L )
ai d u pi s it f it b tr QS D
e
i
•R c e trsacic l u pir oD A a d
o h se i
r ia s p l t L n
t
e
me t aln u t a dD A sa d r s
es lid sr n L tn ad .
y
R c e tr lcrnc , L i c mmi e t
o h se Ee t is L C s o
o
tdo
t
s p ligp o u t ta s t f c so r x e t-
u pyn rd cs h t ai y u tme e p ca
s
t n fr u lya daee u loto eoiial
i s o q ai n r q a t h s r n l
o
t
g
y
s p l db id sr ma ua trr.
u pi
e yn ut
y n fcues
T eoiia ma ua trr d ts e t c o a yn ti d c me t e e t tep r r n e
h r n l n fcue’ aa h e a c mp n ig hs o u n r cs h ef ma c
g
s
o
a ds e ic t n o teR c e tr n fcue v rino ti d vc . o h se Ee t n
n p c ai s f h o h se ma ua trd eso f hs e ie R c e tr lcr -
o
o
isg aa te tep r r n eo i s mio d co p o u t t teoiia OE s e ic -
c u rne s h ef ma c ft e c n u tr rd cs o h r n l M p c a
o
s
g
t n .T pc lv le aefr eee c p r o e o l. eti mii m o ma i m rt g
i s ‘y ia’ au s r o rfrn e up s s ny C r n nmu
o
a
r xmu ai s
n
ma b b s do p o u t h rceiain d sg , i lt n o s mpetsig
y e a e n rd c c aa tr t , e in smuai , r a l e t .
z o
o
n
© 2 1 R cetr l t n s LC Al i t R sre 0 1 2 1
0 3 ohs E cr i , L . lRg s eevd 7 1 0 3
e e oc
h
T l r m r, l s v iw wrcl . m
o e n oe p ae it w . e c o
a
e
s
o ec
CAT5113
100-Tap Digitally Programmable Potentiometer (DPP™)
FEATURES
I
100-position linear taper potentiometer
I
Non-volatile EEPROM wiper storage
I
10nA ultra-low standby current
I
Single supply operation: 2.5V-6.0V
I
Increment Up/Down serial interface
I
Resistance values: 1kΩ ,10kΩ , 50kΩ and 100kΩ
Ω
Ω
Ω
Ω
I
Available in PDIP, SOIC, TSSOP and MSOP packages
H
GEN
FR
ALO
EE
LE
APPLICATIONS
I
Automated product calibration
I
Remote control adjustments
I
Offset, gain and zero control
I
Tamper-proof calibrations
A
D
F
R
E
E
TM
I
Contrast, brightness and volume controls
I
Motor controls and feedback systems
I
Programmable analog functions
DESCRIPTION
The CAT5113 is a single digitally programmable
potentiometer (DPP™) designed as a electronic
replacement for mechanical potentiometers and trim
pots. Ideal for automated adjustments on high volume
production lines, they are also well suited for
applications where equipment requiring periodic
adjustment is either difficult to access or located in a
hazardous or remote environment.
The CAT5113 contains a 100-tap series resistor array
connected between two terminals R
H
and R
L
. An up/
down counter and decoder that are controlled by three
input pins, determines which tap is connected to the
wiper, R
W
. The wiper setting, stored in nonvolatile
memory, is not lost when the device is powered
down and is automatically reinstated when power
is returned. The wiper can be adjusted to test
new system values without effecting the stored
setting. Wiper-control of the CAT5113 is
accomplished with three input control pins,
CS,
U/D,
and
INC.
The
INC
input increments the wiper in the
direction which is determined by the logic state of
the U/D input. The
CS
input is used to select the
device and also store the wiper position prior to
power down.
The digitally programmable potentiometer can be
used as a three-terminal resistive divider or as a
two-terminal variable resistor. DPPs bring variability and
programmability to a wide variety of applications
including control, parameter adjustments, and
signal processing.
FUNCTIONAL DIAGRAM
V
H
/R
H
Vcc
(Supply Voltage)
U/D
INC
CS
7-BIT
UP/DOWN
COUNTER
99
R
H
/ V
H
98
R
H
/ V
H
97
7-BIT
NONVOLATILE
MEMORY
ONE
28
OF
ONE HUNDRED
DECODER
UP/DOWN
(U/D)
INCREMENT
(INC)
DEVICE SELECT
(CS)
POR
Control
and
Memory
R
W
/ V
W
TRANSFER
GATES
RESISTOR
ARRAY
V
W
/ R
W
2
R
L
/ V
L
Vcc
V
SS
STORE AND
RECALL
CONTROL
CIRCUITRY
1
GND
GENERAL
0
R
L
/ V
L
R
W
/ V
W
V
L
/ R
L
GENERAL
DETAILED
ELECTRONIC POTENTIOMETER
IMPLEMENTATION
© 2005 by Catalyst Semiconductor, Inc.
Characteristics subject to change without notice
1
Doc. No. 2009, Rev. R
CAT5113
PIN CONFIGURATION
DIP Package (P, L)
INC
U/D
R
H
GND
1
2
3
4
8
7
6
5
V
CC
CS
R
L
R
W
PIN FUNCTIONS
TSSOP Package (U, Y)
CS
V
CC
INC
U/D
1
2
3
4
8
7
6
5
R
L
R
W
GND
R
H
Pin Name
INC
U/D
R
H
GND
Function
Increment Control
Up/Down Control
Potentiometer High Terminal
Ground
Potentiometer Wiper Terminal
Potentiometer Low Terminal
Chip Select
Supply Voltage
SOIC Package (S, V)
INC
U/D
R
H
GND
1
2
3
4
8
7
6
5
V
CC
CS
R
L
R
W
MSOP Package (R, Z)
INC
U/D
R
H
GND
1
2
3
4
8
7
6
5
V
CC
CS
R
L
R
W
R
W
R
L
CS
V
CC
PIN DESCRIPTIONS
INC:
INC
Increment Control Input
The
INC
input moves the wiper in the up or down direction
determined by the condition of the U/D input.
U/D
: Up/Down Control Input
D
The U/D input controls the direction of the wiper
movement. When in a high state and
CS
is low, any high-
to-low transition on
INC
will cause the wiper to move one
increment toward the R
H
terminal. When in a low state
and
CS
is low, any high-to-low transition on
INC
will
cause the wiper to move one increment towards the
R
L
terminal.
R
H:
High End Potentiometer Terminal
R
H
is the high end terminal of the potentiometer. It is not
required that this terminal be connected to a potential
greater than the R
L
terminal. Voltage applied to the R
H
terminal cannot exceed the supply voltage, V
CC
or go
below ground, GND.
R
W
: Wiper Potentiometer Terminal
R
W
is the wiper terminal of the potentiometer. Its position
on the resistor array is controlled by the control inputs,
INC,
U/D and
CS.
Voltage applied to the R
W
terminal cannot
exceed the supply voltage, V
CC
or go below ground, GND.
R
L
: Low End Potentiometer Terminal
R
L
is the low end terminal of the potentiometer. It is not
required that this terminal be connected to a potential
less than the R
H
terminal. Voltage applied to the R
L
terminal cannot exceed the supply voltage, V
CC
or go
below ground, GND. R
L
and R
H
are electrically
interchangeable.
CS:
CS
Chip Select
The chip select input is used to activate the control input
of the CAT5113 and is active low. When in a high
state, activity on the
INC
and U/D inputs will not
affect or change the position of the wiper.
DEVICE OPERATION
The CAT5113 operates like a digitally controlled
potentiometer with R
H
and R
L
equivalent to the high
and low terminals and R
W
equivalent to the mechanical
potentiometer's wiper. There are 100 available tap
positions including the resistor end points, R
H
and R
L
.
There are 99 resistor elements connected in series
between the R
H
and R
L
terminals. The wiper terminal is
connected to one of the 100 taps and controlled by three
inputs,
INC,
U/D and
CS.
These inputs control a seven-
bit up/down counter whose output is decoded to select
the wiper position. The selected wiper position can be
stored in nonvolatile memory using the
INC
and
CS
inputs.
With
CS
set LOW the CAT5113 is selected and will
respond to the U/D and
INC
inputs. HIGH to LOW
transitions on
INC
wil increment or decrement the
wiper (depending on the state of the U/D input and
seven-bit counter). The wiper, when at either fixed
terminal, acts like its mechanical equivalent and does
not move beyond the last position. The value of the
counter is stored in nonvolatile memory whenever
CS
transitions HIGH while the
INC
input is also HIGH. When
the CAT5113 is powered-down, the last stored wiper
counter position is maintained in the nonvolatile memory.
When power is restored, the contents of the memory are
recalled and the counter is set to the value stored.
With
INC
set low, the CAT5113 may be de-selected
and powered down without storing the current wiper
position in nonvolatile memory. This allows the
system to always power up to a preset value stored
in nonvolatile memory.
Doc. No. 2009, Rev. R
2
CAT5113
OPERATION MODES
R
H
INC
High to Low
High to Low
High
Low
X
CS
Low
Low
Low to High
Low to High
High
U/D
High
Low
X
X
X
Operation
Wiper toward H
Wiper toward L
Store Wiper Position
No Store, Return to Standby
Standby
C
H
R
wi
R
WB
C
W
C
L
R
L
Potentiometer
Equivalent Circuit
ABSOLUTE MAXIMUM RATINGS
Supply Voltage
V
CC
to GND ...................................... –0.5V to +7V
Inputs
CS
to GND .............................–0.5V to V
CC
+0.5V
INC
to GND ............................–0.5V to V
CC
+0.5V
U/D to GND ............................–0.5V to V
CC
+0.5V
H to GND ................................–0.5V to V
CC
+0.5V
L to GND ................................–0.5V to V
CC
+0.5V
W to GND ............................... –0.5V to V
CC
+0.5V
RELIABILITY CHARACTERISTICS
Symbol
V
ZAP(1)
I
LTH(1)(2)
T
DR
N
END
Operating Ambient Temperature
Commercial (‘C’ or Blank suffix) ...... 0°C to +70°C
Industrial (‘I’ suffix) ...................... – 40°C to +85°C
Junction Temperature ..................................... +150°C
Storage Temperature ....................... –65°C to +150°C
Lead Soldering (10 sec max) .......................... +300°C
* Stresses above those listed under Absolute Maximum Ratings may
cause permanent damage to the device. Absolute Maximum Ratings
are limited values applied individually while other parameters are
within specified operating conditions, and functional operation at any
of these conditions is NOT implied. Device performance and reliability
may be impaired by exposure to absolute rating conditions for extended
periods of time.
Parameter
ESD Susceptibility
Latch-Up
Data Retention
Endurance
Test Method
MIL-STD-883, Test Method 3015
JEDEC Standard 17
MIL-STD-883, Test Method 1008
MIL-STD-883, Test Method 1003
Min
2000
100
100
1,000,000
Typ
Max
Units
Volts
mA
Years
Stores
DC Electrical Characteristics: V
CC
= +2.5V to +6.0V unless otherwise specified
Power Supply
Symbol Parameter
Conditions
Min
V
CC
I
CC1
I
CC2
ISB
1 (2)
Operating Voltage Range
Supply Current (Increment)
Supply Current (Write)
Supply Current (Standby)
2.5
V
CC
= 6V, f = 1MHz, I
W
=0
V
CC
= 6V, f = 250kHz, I
W
=0
Programming, V
CC
= 6V
V
CC
= 3V
CS=V
CC
-0.3V
U/D, INC=V
CC
-0.3V or GND
Typ
Max
6.0
100
50
1
500
Units
V
µA
mA
µA
µA
0.01
1
Logic Inputs
Symbol
I
IH
I
IL
V
IH1
V
IL1
V
IH2
V
IL2
NOTES:
(1)
(2)
(3)
(4)
Parameter
Input Leakage Current
Input Leakage Current
TTL High Level Input Voltage
TTL Low Level Input Voltage
CMOS High Level Input Voltage
CMOS Low Level Input Voltage
Conditions
V
IN
= V
CC
V
IN
= 0V
4.5V
≤
V
CC
≤
5.5V
2.5V
≤
V
CC
≤
6V
Min
Typ
Max
10
–10
V
CC
0.8
V
CC
+ 0.3
V
CC
x 0.2
Units
µA
µA
V
V
V
V
2
0
V
CC
x 0.7
-0.3
This parameter is tested initially and after a design or process change that affects the parameter.
Latch-up protection is provided for stresses up to 100mA on address and data pins from –1V to V
CC
+ 1V
I
W
=source or sink
These parameters are periodically sampled and are not 100% tested.
3
Doc. No. 2009, Rev. R
CAT5113
Potentiometer Parameters
Symbol
R
POT
Parameter
Potentiometer Resistance
Conditions
-01 Device
-50 Device
-50 Device
-00 Device
Pot Resistance Tolerance
V
RH
V
RL
INL
DNL
R
Wi
I
W
TC
RPOT
TC
RATIO
V
N
C
H
/C
L
/C
W
fc
Voltage on R
H
pin
Voltage on R
L
pin
Resolution
Integral Linearity Error
Differential Linearity Error
Wiper Resistance
Wiper Current
TC of Pot Resistance
Ratiometric TC
Noise
Potentiometer Capacitances
Frequency Response
Passive Attenuator, 10kΩ
100kHz / 1kHz
8/24
8/8/25
1.7
I
W
≤
2µA
I
W
≤
2µA
V
CC
= 5V, I
W
= 1mA
V
CC
= 2.5V, I
W
= 1mA
(1)
-4.4
300
20
0
0
1%
0.5
0.25
1
0.5
400
1
4.4
Min
Typ
1
50
50
100
±20
V
CC
V
CC
%
V
V
%
LSB
LSB
Ω
kΩ
mA
ppm/
o
C
ppm/
o
C
nV/ H
z
pF
MHz
kΩ
Max
Units
Note:
1. This parameter is not 100% tested.
Doc. No. 2009, Rev. R
4
