19-3195; Rev 1; 2/05
Dual, Low-Power, 500Mbps ATE
Driver/Comparator with 35mA Load
General Description
The MAX9967 dual, low-power, high-speed, pin electron-
ics driver/comparator/load (DCL) IC includes, for each
channel, a three-level pin driver, a dual comparator, vari-
able clamps, and an active load. The driver features a
wide voltage range and high-speed operation, includes
high-impedance and active-termination (3rd-level drive)
modes, and is highly linear even at low-voltage swings.
The dual comparator provides low dispersion (timing
variation) over a wide variety of input conditions. The
clamps provide damping of high-speed device-under-
test (DUT) waveforms when the device is configured as a
high-impedance receiver. The programmable load sup-
plies up to 35mA of source and sink current. The load
facilitates contact/continuity testing, at-speed parametric
testing of IOH and IOL, and pullup of high-output-imped-
ance devices.
The MAX9967A provides tight matching of gain and off-
set for the drivers, and offset for the comparators and
active load, allowing reference levels to be shared
across multiple channels in cost-sensitive systems. Use
the MAX9967B for system designs that incorporate
independent reference levels for each channel.
The MAX9967 provides high-speed, differential control
inputs with optional internal termination resistors that
are compatible with ECL, LVPECL, LVDS, and GTL.
ECL/LVPECL or flexible open-collector outputs with
optional internal pullup resistors are available for the
comparators. These features significantly reduce the
discrete component count on the circuit board.
A 3-wire, low-voltage, CMOS-compatible serial interface
programs the low-leakage, slew-rate limit, and tri-
state/terminate operational configurations of the
MAX9967.
The MAX9967’s operating range is -1.5V to +6.5V with
power dissipation of only 1.15W per channel. The
device is available in a 100-pin, 14mm x 14mm body,
and 0.5mm pitch TQFP. An exposed 8mm x 8mm die
pad on the top of the package facilitates efficient heat
removal. The device is specified to operate with an
internal die temperature of +70°C to +100°C, and
features a die temperature monitor output.
♦
High Speed: 500Mbps at 3V
P-P
♦
Programmable 35mA Active-Load Current
♦
Low Timing Dispersion
♦
Wide -1.5V to +6.5V Operating Range
♦
Active Termination (3rd-Level Drive)
♦
Low Leakage Mode: 60nA
♦
Integrated Clamps
♦
Interfaces Easily with Most Logic Families
♦
Integrated PMU Connection
♦
Digitally Programmable Slew Rate
♦
Internal Termination Resistors
♦
Low Gain and Offset Error
Features
♦
Low Power Dissipation: 1.15W/Channel (typ)
MAX9967
Ordering Information
PART
MAX9967ADCCQ*
MAX9967AGCCQ*
MAX9967ALCCQ
MAX9967AMCCQ*
MAX9967AQCCQ*
MAX9967ARCCQ*
MAX9967BDCCQ
MAX9967BGCCQ
MAX9967BLCCQ
MAX9967BMCCQ
MAX9967BQCCQ*
MAX9967BRCCQ
TEMP RANGE
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
0°C to +70°C
PIN-PACKAGE
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
100 TQFP-EPR**
*Future
product—contact factory for availability.
**EPR
= Exposed pad reversed (TOP).
Pin Configuration and Typical Application Circuits appear at
end of data sheet.
Selector Guide appears at end of data sheet.
Applications
Low-Cost Mixed-Signal/System-on-Chip ATE
Commodity Memory ATE
PCI or VXI Programmable Digital Instruments
________________________________________________________________
Maxim Integrated Products
1
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
Dual, Low-Power, 500Mbps ATE
Driver/Comparator with 35mA Load
MAX9967
ABSOLUTE MAXIMUM RATINGS
V
CC
to GND .........................................................-0.3V to +11.5V
DHV_ to DTV_........................................................…………±10V
V
EE
to GND............................................................-7.0V to +0.3V
DLV_ to DTV_ ........................................................…………±10V
V
CC
- V
EE
................................................................-0.3V to +18V
CHV_ or CLV_ to DUT_..........................................…………±10V
GS to GND ...........................................................……………±1V
CH_, NCH_, CL_, NCL_ to GND (open collector) ....-2.5V to +5V
DUT_, LDH_, LDL_ to GND ...................................-2.5V to +7.5V
CH_, NCH_, CL_, NCL_ to GND (open emitter) ..(V
CCO
_ + 1.0V)
All Other Pins to GND ......................(V
EE
- 0.3V) to (V
CC
+ 0.3V)
DATA_, NDATA_, RCV_, NRCV_,
Current Out of CH_, NCH_, CL_, NCL_ (open emitter) ....+50mA
LDEN_, NLDEN_ to GND ...............................…-2.5V to +5.0V
DHV_, DLV_, DTV_, CHV_, CLV_,
DATA_ to NDATA_, RCV_ to NRCV_,
CPHV_, CPLV_ Current.....................................……….±10mA
LDEN_ to NLDEN_............................................…………±1.5V
TEMP Current...................................................-0.5mA to +20mA
V
CCO_
to GND ..........................................................-0.3V to +5V
SCLK, DIN,
CS, RST,
TDATA_,
DUT_ Short Circuit to -1.5V to +6.5V..........................Continuous
TRCV_, TLDEN_ to GND ..................................…-1.0V to +5V
Power Dissipation (T
A
= +70°C)
MAX9967_ _CCQ (derate 167mW/°C above +70°C) ....13.3W*
DHV_, DLV_, DTV_, CHV_, CLV_, COM_,
Storage Temperature Range .............................-65°C to +150°C
FORCE_, SENSE_ to GND.................................-2.5V to +7.5V
Junction Temperature ......................................................+125°C
CPHV_ to GND ......................................................-2.5V to +8.5V
Lead Temperature (soldering, 10s) ....................………..+300°C
CPLV_ to GND.......................................................-3.5V to +7.5V
DHV_ to DLV_........................................................…………±10V
*Dissipation
wattage values are based on still air with no heat sink. Actual maximum allowable power dissipation is a function of heat
extraction technique and may be substantially higher.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(V
CC
= +9.75V, V
EE
= -5.25V, V
CCO_
= +2.5V, SC1 = SC0 = 0, V
CPHV_
= +7.2V, V
CPLV_
= -2.2V, V
LDH
_ = V
LDL
_ = 0, V
GS
= 0,
T
J
= +85°C,
unless otherwise noted. All temperature coefficients are measured at T
J
= +70°C to +100°C, unless otherwise noted.) (Note 1)
PARAMETER
POWER SUPPLIES
Positive Supply
Negative Supply
Positive Supply Current
(Note 2)
V
CC
V
EE
V
LDH
_ = V
LDL
_ = 0
I
CC
V
LDH
_ = V
LDL
_ = 3.5V, load enabled,
driver = high impedance
V
LDH
_ = V
LDL
_ = 0
I
EE
P
D
V
DUT
I
DUT
V
LDH
_ = V
LDL
_ = 3.5V, load enabled,
driver = high impedance
(Notes 2, 3)
(Note 4)
LLEAK = 0; 0
≤
V
DUT
_
≤
3V
LLEAK = 0; V
DUT
_ = -1.5V, +6.5V
LLEAK = 1; 0
≤
V
DUT
_
≤
3V, T
J
< +90°C
LLEAK = 1; V
DUT
_ = -1.5V, +6.5V;
T
J
< +90°C
Leakage Current in Low-Leakage
Mode
LLEAK = 1; 0 < V
DUT
_ < 3V, V
LDL
_=
V
LDH
_ = 3.5V; T
J
< +90°C
LLEAK = 1; V
DUT
_ = -1.5V, +6.5V;
V
LDL
_ = V
LDH
_ = 3.5V; T
J
< +90°C
-1.5
9.5
-6.5
9.75
-5.25
120
220
-220
-320
2.3
10.5
-4.5
155
255
-265
-365
2.9
+6.5
±1.5
±3
±60
±110
±80
±160
nA
mA
W
V
µA
mA
V
V
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
Negative Supply Current
(Note 2)
Power Dissipation
DUT_ CHARACTERISTICS
Operating Voltage Range
Leakage Current in High-
Impedance Mode
2
_______________________________________________________________________________________
Dual, Low-Power, 500Mbps ATE
Driver/Comparator with 35mA Load
ELECTRICAL CHARACTERISTICS (continued)
(V
CC
= +9.75V, V
EE
= -5.25V, V
CCO_
= +2.5V, SC1 = SC0 = 0, V
CPHV_
= +7.2V, V
CPLV_
= -2.2V, V
LDH
_ = V
LDL
_ = 0, V
GS
= 0,
T
J
= +85°C, unless otherwise noted. All temperature coefficients are measured at T
J
= +70°C to +100°C, unless otherwise noted.) (Note 1)
PARAMETER
Combined Capacitance
Low-Leakage Enable Time
Low-Leakage Disable Time
Low-Leakage Recovery
SYMBOL
C
DUT
CONDITIONS
Driver in term mode (DUT_ = DTV_)
Driver in high-impedance mode
(Notes 5, 6)
(Notes 6, 7)
Time to return to the specified maximum
leakage after a 3V, 4V/ns step at DUT_
I
BIAS
To 0.1% of full-scale change (Note 7)
V
IH
V
IL
V
DIFF
MAX9967_DCCQ, MAX9967_MCCQ
V
TDATA
_,
V
TRCV
_,
V
TLDEN
_
MAX9967_GCCQ, MAX9967_LCCQ, and
MAX9967_QCCQ
MAX9967_GCCQ, MAX9967_LCCQ, and
MAX9967_QCCQ, between signal and
corresponding termination voltage input
V
THRINT
R
O
V
THR
V
IH
V
IL
I
B
f
SCLK
t
CH
t
CL
t
CSS0
t
CSS1
8
8
3.5
3.5
0.43
V
THR
+
0.2
-0.1
-2.1
-1.6
-2.0
±0.15
1
+3.5
+3.1
±1.0
±25
+3.5
MIN
TYP
4.0
8.0
20
20
4
MAX
UNITS
pF
µs
µs
µs
MAX9967
LEVEL PROGRAMMING INPUTS (DHV_, DLV_, DTV_, CHV_, CLV_, CPHV_, CPLV_, COM_, LDH_, LDL_)
Input Bias Current
Settling time
Input High Voltage
Input Low Voltage
Differential Input Voltage
Input Bias Current
Input Termination Voltage
±25
µA
µs
V
V
V
µA
V
DIFFERENTIAL CONTROL INPUTS (DATA_, NDATA_, RCV_, NRCV_, LDEN_, NLDEN_)
Input Termination Resistor
48
52
Ω
SINGLE-ENDED CONTROL INPUTS (CS, SCLK, DIN,
RST)
Internal Threshold Reference
Internal Reference Output
Resistance
External Threshold Reference
Input High Voltage
Input Low Voltage
Input Bias Current
SERIAL INTERFACE TIMING
(Figure 6)
SCLK Frequency
SCLK Pulse-Width High
SCLK Pulse-Width Low
CS
Low to SCLK High Setup
CS
High to SCLK High Setup
50
MHz
ns
ns
ns
ns
1.05
1.25
20
1.73
3.5
V
THR
-
0.2
±25
1.45
V
kΩ
V
V
V
µA
_______________________________________________________________________________________
3
Dual, Low-Power, 500Mbps ATE
Driver/Comparator with 35mA Load
MAX9967
ELECTRICAL CHARACTERISTICS (continued)
(V
CC
= +9.75V, V
EE
= -5.25V, V
CCO_
= +2.5V, SC1 = SC0 = 0, V
CPHV_
= +7.2V, V
CPLV_
= -2.2V, V
LDH
_ = V
LDL
_ = 0, V
GS
= 0,
T
J
= +85°C, unless otherwise noted. All temperature coefficients are measured at T
J
= +70°C to +100°C, unless otherwise noted.) (Note 1)
PARAMETER
SCLK High to
CS
High Hold
DIN to SCLK High Setup
DIN to SCLK High Hold
CS
Pulse Width High
TEMPERATURE MONITOR (TEMP)
Nominal Voltage
Temperature Coefficient
Output Resistance
DRIVERS (Note 8)
DC OUTPUT CHARACTERISTICS (R
L
≥
10MΩ)
DHV_, DLV_, DTV_, Output Offset
Voltage
DHV_, DLV_, DTV_, Output Offset
Temperature Coefficient
DHV_, DLV_, DTV_, Gain
DHV_, DLV_, DTV_, Gain
Temperature Coefficient
Linearity Error
DHV_ to DLV_ Crosstalk
DLV_ to DHV_ Crosstalk
DTV_ to DLV_ and DHV_
Crosstalk
DHV_ to DTV_ Crosstalk
DLV_ to DTV_ Crosstalk
DHV_, DTV_, DLV_ DC Power-
Supply Rejection Ratio
Maximum DC Drive Current
DC Output Resistance
DC Output Resistance Variation
PSRR
I
DUT
_
R
DUT
_
∆R
DUT
_
I
DUT
_ =
±30mA
(Note 13)
I
DUT
_ =
±1mA
to
±8mA
I
DUT
_ =
±1mA
to
±40mA
V
DUT
= 1.5V, 3V (Note 10)
Full range (Notes 10, 11)
V
DLV
_ = 0;
V
DHV
_ = 200mV, 6.5V
V
DHV
_ = 5V;
V
DLV
_ = -1.5V, +4.8V
V
DHV
_ = 3V; V
DLV
_ = 0;
V
DTV
_ = -1.5V, +6.5V
V
DTV
_ = 1.5V; V
DLV
_ = 0;
V
DHV
_ = 1.6V, 3V
V
DTV
_ = 1.5V; V
DHV
_ = 3V; V
DLV
_ = 0, 1.4V
(Note 12)
40
±60
49
50
0.5
1
2.5
±120
51
A
V
Measured with V
DHV
_, V
DLV
_,
and V
DTV
_ at 0 and 4.5V
MAX9967A
(Note 9)
MAX9967B
0.999
0.96
-35
±5
±15
±2
±2
±2
±3
±3
V
OS
At DUT_ with V
DHV
_, V
DTV
_,
V
DLV
_ independently tested
at +1.5V
MAX9967A
MAX9967B
±65
1.00
1.001
1.001
ppm/°C
mV
mV
mV
mV
mV
mV
dB
mA
Ω
Ω
±15
±100
mV
µV/°C
T
J
= +70°C, R
L
≥
10MΩ
3.43
+10
15
V
mV/°C
kΩ
SYMBOL
t
CSH1
t
DS
t
DH
t
CSWH
CONDITIONS
MIN
3.5
3.5
3.5
20
TYP
MAX
UNITS
ns
ns
ns
ns
V/V
4
_______________________________________________________________________________________
Dual, Low-Power, 500Mbps ATE
Driver/Comparator with 35mA Load
ELECTRICAL CHARACTERISTICS (continued)
(V
CC
= +9.75V, V
EE
= -5.25V, V
CCO_
= +2.5V, SC1 = SC0 = 0, V
CPHV_
= +7.2V, V
CPLV_
= -2.2V, V
LDH
_ = V
LDL
_ = 0, V
GS
= 0,
T
J
= +85°C, unless otherwise noted. All temperature coefficients are measured at T
J
= +70°C to +100°C, unless otherwise noted.) (Note 1)
PARAMETER
Sense Resistance
Force Resistance
Force Capacitance
SYMBOL
R
SENSE
R
FORCE
C
FORCE
V
DLV
_ = 0, V
DHV
_ = 0.1V
Drive-Mode Overshoot
Term-Mode Overshoot
Settling Time to Within 25mV
Settling Time to Within 5mV
Prop Delay, Data to Output
Prop Delay Match, t
LH
vs. t
HL
Prop Delay Match, Drivers Within
Package
Prop Delay Temperature
Coefficient
Prop Delay Change vs. Pulse
Width
Prop Delay Change vs. Common-
Mode Voltage
Prop Delay, Drive to High
Impedance
Prop Delay, High Impedance to
Drive
Prop Delay, Drive to Term
Prop Delay, Term to Drive
t
PDDZ
t
PDZD
t
PDDT
t
PDTD
3V
P-P
, 40MHz, 2.5ns to 22.5ns pulse width,
relative to 12.5ns pulse width
V
DHV
_ - V
DLV
_ = 1V, V
DHV
_ = 0 to 6V
V
DHV
_ = 1.0V, V
DLV
_ = -1.0V, V
DTV
_ = 0
V
DHV
_ = 1.0V, V
DLV
_ = -1.0V, V
DTV
_ = 0
V
DHV
_ = 3V, V
DLV
_ = 0, V
DTV
_ = 1.5V
V
DHV
_ = 3V, V
DLV
_ = 0, V
DTV
_ = 1.5V
0.2V
P-P,
20% to 80%
Rise and Fall Time
t
R
, t
F
1V
P-P,
10% to 90%
3V
P-P,
10% to 90%
5V
P-P,
10% to 90%
Rise and Fall Time Match
SC1 = 0, SC0 = 1 Slew Rate
SC1 = 1, SC0 = 0 Slew Rate
SC1 = 1, SC0 = 1 Slew Rate
t
R
vs. t
F
3V
P-P,
10% to 90%
Percent of full speed (SC0 = SC1 = 0),
3V
P-P
, 20% to 80%
Percent of full speed (SC0 = SC1 = 0),
3V
P-P
, 20% to 80%
Percent of full speed (SC0 = SC1 = 0),
3V
P-P
, 20% to 80%
1.0
t
PDD
3V
P-P
(Note 17)
V
DLV
_ = 0, V
DHV
_ = 1V
V
DLV
_ = 0, V
DHV
_ = 3V
(Note 14)
3V step (Note 15)
3V step (Note 15)
CONDITIONS
MIN
7.50
320
TYP
10
400
2
30
40
50
0
10
20
2.2
±50
40
+3
±60
85
3.2
3.3
2.5
2.2
370
630
1.3
2.0
±0.03
75
50
25
1.5
mV
ns
ns
ns
ps
ps
ps/°C
ps
ps
ns
ns
ns
ns
mV
MAX
13.75
500
UNITS
kΩ
Ω
pF
MAX9967
DYNAMIC OUTPUT CHARACTERISTICS (Z
L
= 50Ω)
TIMING CHARACTERISTICS (Z
L
= 50Ω) (Note 16)
DYNAMIC PERFORMANCE (Z
L
= 50Ω)
ps
ns
ns
%
%
%
_______________________________________________________________________________________
5