LINER LT1394 7ns, low power, single supply, ground-sensing comparator Datasheet

LT1394
7ns, Low Power,
Single Supply, Ground-Sensing
Comparator
DESCRIPTIO
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FEATURES
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UltraFastTM: 7ns
Low Power: 6mA
Low Offset Voltage: 0.8mV
Operates Off Single 5V or Dual ±5V Supplies
Input Common Mode Extends to Negative Supply
No Minimum Input Slew Rate Requirement
Complementary TTL Outputs
Inputs Can Exceed Supplies without Phase Reversal
Pin Compatible with LT1016, LT1116 and LT1671
Output Latch Capability
Available in 8-Lead MSOP and SO Packages
The LT ®1394 is an UltraFast (7ns) comparator with complementary outputs and latch. The input common mode range
extends from 1.5V below the positive supply down to the
negative supply rail. Like the LT1016, LT1116 and LT1671,
this comparator has complementary outputs designed to
interface directly to TTL or CMOS logic. The LT1394 may
operate from either a single 5V supply or dual ±5V supplies.
Low offset voltage specifications and high gain allow the
LT1394 to be used in precision applications.
The LT1394 is designed for improved speed and stability for
a wide range of operating conditions. The output stage
provides active drive in both directions for maximum speed
into TTL, CMOS or passive loads with minimal cross-conduction current. Unlike other fast comparators, the LT1394
remains stable even for slow transitions through the active
region, which eliminates the need to specify a minimum input
slew rate.
The LT1394 has an internal, TTL/CMOS compatible latch for
retaining data at the outputs. The latch holds data as long as
the LATCH pin is held high. Device parameters such as gain,
offset and negative power supply current are not significantly
affected by variations in negative supply voltage.
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APPLICATIO S
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High Speed A/D Converters
Zero-Crossing Detectors
Current Sense for Switching Regulators
Extended Range V/F Coverters
Fast Pulse Height/Width Discriminators
High Speed Triggers
Line Receivers
High Speed Sampling Circuits
, LTC and LT are registered trademarks of Linear Technology Corporation.
UltraFast is a trademark of Linear Technology Corporation.
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TYPICAL APPLICATIO
45MHz Single Supply Adaptive Trigger
Propagation Delay vs
Input Overdrive
5V
2k
12
5
Q2
+
3M
4
2
500pF
0.005µF
A1
LT1227
–
13
750Ω
510Ω
5V
Q3
36Ω
15
0.1µF
Q1, Q2, Q3, Q4 = CA3096 ARRAY:
TIE SUBSTRATE (PIN 16) TO GROUND
= 1N4148
Q4
100µF
0.1µF
tPDLH
6
tPDHL
4
2
11
470Ω
0
+
+
10µF +
A2
LT1006
3M
10
14 12
8
5V
+
0.005µF
–
2k
10
TIME (ns)
1
Q1
5V
TA = 25°C
VSTEP = 100mV
VS = ±5V
6
3
2k
470Ω
0.1µF
–
LT1394
TRIGGER
OUT
0
10
20
30
OVERDRIVE (mV)
40
50
1394 TA02
INPUT
1394 F18
1
LT1394
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ABSOLUTE MAXIMUM RATINGS
(Note 1)
Total Supply Voltage (V+ to V–) ............................... 12V
Positive Supply Voltage ............................................. 7V
Negative Supply Voltage .......................................... – 7V
Differential Input Voltage ....................................... ±12V
Input and Latch Current (Note 2) ........................ ±10mA
Output Current (Continuous)(Note 2) ................. ±20mA
Operating Temperature Range ................ – 40°C to 85°C
Specified Temperature Range (Note 3) ... – 40°C to 85°C
Junction Temperature ........................................... 150°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
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PACKAGE/ORDER INFORMATION
ORDER PART
NUMBER
TOP VIEW
V+
+IN
–IN
V–
1
2
3
4
8
7
6
5
Q OUT
Q OUT
GND
LATCH
ENABLE
MS8 PACKAGE
8-LEAD PLASTIC MSOP
LT1394CMS8
V+ 1
+IN 2
–IN 3
MS8 PART MARKING
TJMAX = 150°C, θJA = 250°C/ W
ORDER PART
NUMBER
TOP VIEW
V– 4
LTBH
8 Q OUT
+
–
LT1394CS8
LT1394IS8
7 Q OUT
6 GND
5
LATCH
ENABLE
S8 PART MARKING
S8 PACKAGE
8-LEAD PLASTIC SO
1394
1394I
TJMAX = 150°C, θJA = 190°C/ W
Consult factory for Military grade parts.
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25°C.
V + = 5V, V – = – 5V, VOUT(Q) = 1.4V, VLATCH = VCM = 0V unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
VOS
Input Offset Voltage
RS ≤ 100Ω (Note 4)
MIN
TYP
MAX
UNITS
0.8
2.5
4.0
mV
mV
●
∆VOS
∆T
IOS
Input Offset Voltage Drift
Input Offset Current
0.1
0.5
0.8
µA
µA
2
4.5
7.0
µA
µA
3.5
3.5
V
V
●
IB
Input Bias Current
(Note 5)
●
VCMR
Input Voltage Range (Note 6)
Single 5V Supply
CMRR
Common Mode Rejection Ratio
–5
0
– 5V ≤ VCM ≤ 3.5V, TA > 0°C
– 5V ≤ VCM ≤ 3.3V, TA ≤ 0°C
55
55
100
dB
dB
Single 5V Supply
0V ≤ VCM ≤ 3.5V, TA > 0°C
0V ≤ VCM ≤ 3.3V, TA ≤ 0°C
55
55
100
dB
dB
50
65
65
100
dB
dB
750
1600
V/V
2.7
2.4
3.1
3.0
4.6V ≤ V + ≤ 5.4V
– 7V ≤ V – ≤ – 2V
PSRR
Power Supply Rejection Ratio
AV
Small Signal Voltage Gain
1V ≤ VOUT ≤ 2V
VOH
Output Voltage Swing High
V + ≥ 4.6V, IOUT = 1mA
V + ≥ 4.6V, IOUT = 4mA
2
●
●
µV/°C
4
●
●
●
●
●
V
V
LT1394
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25°C.
V + = 5V, V – = – 5V, VOUT(Q) = 1.4V, VLATCH = VCM = 0V unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
VOL
Output Voltage Swing Low
IOUT = – 4mA
IOUT = – 10mA
I+
Positive Supply Current
MIN
●
TYP
MAX
UNITS
0.3
0.4
0.5
V
V
6
8.5
10.0
mA
mA
1.2
2.2
2.5
mA
mA
●
I–
Negative Supply Current
●
VIH
LATCH Pin High Input Voltage
●
VIL
LATCH Pin Low Input Voltage
●
IIL
LATCH Pin Current
VLATCH = 0V
t PD
Propagation Delay (Note 7)
∆VIN = 100mV, VOD = 5mV
●
2
V
0.8
V
–4
– 10
µA
7
9
14
ns
ns
0.5
2.2
ns
●
∆t PD
Differential Propagation Delay (Note 7)
∆VIN = 100mV, VOD = 5mV
t LPD
Latch Propagation Delay (Note 8)
6
ns
t SU
Latch Setup Time (Note 8)
– 0.4
ns
tH
Latch Hold Time (Note 8)
2
ns
t PW(D)
Minimum Disable Pulse Width
3
ns
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: This parameter is guaranteed to meet specified perforamnce
through design and characterization. It has not been tested.
Note 3: The LT1394CMS8 and LT1394CS8 are guaranteed to meet
specified performance from 0°C to 70°C and are designed, characterized
and expected to meet these extended temperature limits, but are not tested
at – 40°C and 85°C. The LT1394IS8 is guaranteed to meet the extended
temperature limits.
Note 4: Input offset voltage (VOS) is defined as the average of the two
voltages measured by forcing first one output, then the other to 1.4V.
Note 5: Input bias current (IB) is defined as the average of the two input
currents.
Note 6: Input voltage range is guaranteed in part by CMRR testing and in
part by design and characterization.
Note 7: tPD and ∆tPD cannot be measured in automatic handling
equipment with low values of overdrive. The LT1394 is 100% tested with a
100mV step and 20mV overdrive. Correlation tests have shown that tPD
and ∆tPD limits can be guaranteed with this test, if additional DC tests are
performed to guarantee that all internal bias conditions are correct.
Propagation delay (t PD) is measured with the overdrive added to the actual
VOS. Differential propagation delay is defined as:
∆t PD = t PDLH – t PDHL
Note 8: Latch propagation delay (t LPD) is the delay time for the output to
respond when the LATCH pin is deasserted. Latch setup time (t SU) is the
interval in which the input signal must remain stable prior to asserting the
latch signal. Latch hold time (tH) is the interval after the latch is asserted in
which the input signal must remain stable.
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LT1394
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TYPICAL PERFORMANCE CHARACTERISTICS
Propagation Delay vs
Load Capacitance
Gain Characteristics
12
12
5.0
VS = ±5V
IOUT = 0
4.5
TA = 125°C
4.0
10
10
tPDLH
TA = 25°C
3.5
tPDHL
3.0
2.5
TA = –55°C
2.0
TIME (ns)
8
TIME (ns)
OUTPUT VOLTAGE (V)
Propagation Delay vs
Positive Supply Voltage
6
4
1.5
1.0
0.5
0
0
–3
–2
0
1
2
–1
DIFFERENTIAL INPUT VOLTAGE (mV)
3
6
tPDLH
0
0
V – = –5V
TA = 25°C
VSTEP = 100mV
OVERDRIVE = 5mV
2
10
20
30
40
OUTPUT LOAD CAPACITANCE (pF)
50
4.4
4.6
4.8
5.0
5.2
5.4
POSITIVE SUPPLY VOLTAGE (V)
Propagation Delay vs
Input Overdrive
Propagation Delay vs
Source Resistance
80
12
TA = 25°C
VSTEP = 100mV
VS = ±5V
Propagation Delay vs
Temperature
12
VS = ±5V
VOD = 20mV
TA = 25°C
70
10
VS = ±5V
VSTEP = 100mV
VOD = 5mV
60
tPDLH
6
tPDHL
50
40
400mV
STEP SIZE = 800mV
30
4
tPDLH
8
TIME (ns)
TIME (ns)
TIME (ns)
8
5.6
1394 G03
1394 G02
1394 G01
10
tPDHL
4
IOUT = 0
VS = ±5V
TA = 25°C
VSTEP = 100mV
OVERDRIVE = 5mV
2
8
tPDHL
6
4
20
2
0
100mV
10
0
0
10
20
30
OVERDRIVE (mV)
40
50
0
0.5
2
200mV
2.5
1.0
1.5
2.0
SOURCE RESISTANCE (kΩ)
0
–50 –25
3.0
1394 G04
1394 TA02
6
VS = ±5V
VS = ±5V
VS = ±5V
1
–1
–2
–3
3
VOLTAGE (V)
INPUT BIAS CURRENT (µA)
5
0
VOLTAGE (mV)
125
Positive Common Mode Limit vs
Temperature
4
2
100
1394 G05
Input Bias Current vs
Temperature
Input Offset Voltage vs
Temperature
VCM = –5V
2
VCM = 0V
4
3
2
1
VCM = 3.5V
1
–4
–5
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
125
LT1394 G06
4
50
25
75
0
TEMPERATURE (°C)
0
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
125
LT1394 G07
0
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
125
1394 G08
LT1394
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TYPICAL PERFORMANCE CHARACTERISTICS
Negative Common Mode Limit vs
Temperature
1
0.8
0
5.0
VS = ±5V
∆VIN = 30mV
0.7
VS = SINGLE 5V
–3
–4
VS = ±5V
–5
0.5
TA = 125°C
0.4
50
25
75
0
TEMPERATURE (°C)
100
TA = –55°C
0.3
TA = 25°C
0
0
8
6
10 12 14
4
OUTPUT SINK CURRENT (mA)
2
0
V+ = 5V
∆VIN = –60mV
2
CURRENT (mA)
3
10
TA = 125°C
8
6
TA = –55°C
4
TA = –55°C
16
4
TA = 25°C
12
TA = 25°C
3
VS = ±5V
14
CURRENT (mA)
4
8
6
10 12 14
4
OUTPUT SOURCE CURRENT (mA)
Negative Supply Current vs
V – Supply Voltage
16
TA = 125°C
2
1394 G11
Positive Supply Current vs
Switching Frequency
7
2
TA = 125°C
TA = 25°C
TA = –55°C
1
2
1
0
0
0
1
2
7
4
6
5
3
SUPPLY VOLTAGE (V)
8
10
SWITCHING FREQUENCY (MHz)
1
100
Latch Pin Current vs Temperature
–8
–7 –6 –5 –4 –3 –2 –1
NEGATIVE SUPPLY VOLTAGE (V)
VS = ±5V
VLATCH = 0V
6
0
1394 G14
Response to 100MHz ±10mV
Sine Wave
8
7
0
1394 G13
1394 G12
CURRENT (µA)
CURRENT (mA)
1.0
16
1394 G10
V – = 0V
VIN = –60mV
IOUT = 0
5
TA = –55°C
2.5
1.5
125
10
6
TA = 25°C
3.0
0.1
Positive Supply Current vs
V + Supply Voltage
8
TA = 125°C
3.5
2.0
LT1394 G09
9
4.0
0.2
–6
–50 –25
OUTPUT VOLTAGE (V)
–2
VS = ±5V
∆VIN = –30mV
4.5
0.6
–1
VOLTAGE (V)
INPUT VOLTAGE (V)
Output High Voltage (VOH) vs
Output Source Current
Output Low Voltage (VOL) vs
Output Sink Current
5
+ IN
20mVP-P
4
3V
3
Q
OUT
10mV/DIV
1V/DIV
2
0V
1
FET PROBES
0
–50 –25
50
25
75
0
TEMPERATURE (°C)
100
5ns/DIV
1394 G16
125
LT1394 G15
5
LT1394
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TYPICAL PERFORMANCE CHARACTERISTICS
tPD– Response Time to
5mV Overdrive
tPD+ Response Time to
5mV Overdrive
1.4V
5mV
+ IN
–95mV
1.4V
Q OUT
5mV
+ IN
Q OUT
–95mV
0V
VS = ±5V
fIN = 2MHz
VOD = 5mV
VS = ±5V
fIN = 2MHz
VOD = 5mV
2ns/DIV
1394 G17
0V
2ns/DIV
1394 G18
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PIN FUNCTIONS
V + (Pin 1): Positive Supply Voltage. Normally 5V.
GND (Pin 6): Ground.
+IN (Pin 2): Noninverting Input.
Q OUT (Pin 7): Noninverting Logic Output. This pin is high
when +IN is above –IN and LATCH ENABLE is low.
–IN (Pin 3): Inverting Input.
Q OUT (Pin 8): Inverting Logic Output. This pin is low
when +IN is above –IN and LATCH ENABLE is low.
V – (Pin 4): Negative Supply Voltage. Normally either 0V or
– 5V.
LATCH ENABLE (Pin 5): Latch Control Pin. When high, the
outputs remain in a latched condition, independent of the
current state of the inputs.
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TI I G DIAGRA S
VOD
VIN
LATCH
ENABLE
tSU
∆VIN
VIN
tPD
t LPD
VOUT
VOUT
1394 TD01
6
tH
1394 TD02
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APPLICATIONS INFORMATION
Common Mode Considerations
Input Bias Current
The LT1394 is specified for a common mode range of – 5V
to 3.5V on a ±5V supply or a common mode range of 0V
to 3.5V on a single 5V supply. A more general consideration is that the common mode range is 0V below the
negative supply and 1.5V below the positive supply, independent of the actual supply voltage. The criterion for
common mode limit is that the output still responds
correctly to a small differential input signal.
Input bias current is measured with the output held at
1.4V. As with any PNP differential input stage, the LT1394
bias current flows out of the device. It will go to zero on an
input which is high and double on an input which is low.
When either input signal falls below the negative common
mode limit, the internal PN diode formed with the substrate can turn on, resulting in significant current flow
through the die. An external Schottky clamp diode
between the input and the negative rail can speed up
recovery from negative overdrive by preventing the substrate diode from turning on. The zero-crossing detector
in Figure 1 demonstrates the use of a fast clamp diode.
The zero-crossing detector terminates the transmission
line at its 50Ω characteristic impedance. Negative inputs
should not fall below – 2V to keep the signal current within
the clamp diode’s maximum forward rating. Positive
inputs should not exceed the device’s absolute maximum
ratings or the power rating on the terminating resistor.
Either input may go above the positive common mode
limit without damaging the comparator. The upper voltage
limit is determined by an internal diode from each input to
the positive supply. The input may go above the positive
supply as long as it does not go far enough above it to
conduct more than 10mA. Functionality will continue if the
remaining input stays within the allowed common mode
range. There will, however, be an increase in propagation
delay as the input signal switches back into the common
mode range.
RS
50Ω
5V
CABLE
+
VIN
1N5712
RT
50Ω
Q
LT1394
–
Q
1394 F01
Figure 1. Fast Zero-Crossing Detector
LATCH Pin Dynamics
The LATCH pin is intended to retain input data (output
latched) when the LATCH pin goes high. The pin will float
to a high state when disconnected, so a flow-through
condition requires that the LATCH pin be grounded. The
LATCH pin is designed to be driven with either a TTL or
CMOS output. It has no built-in hysteresis.
To guarantee data retention, the input signal must remain
valid at least 2ns after the latch goes high (hold time), and
must be valid at least – 0.4ns before the latch goes high
(setup time). The negative setup time simply means that
the data arriving 0.4ns after (rather than before) the latch
signal is valid. When the latch signal goes low, new data
will appear at the output in approximately 6ns (latch
propagation delay).
Measuring Response Time
To properly measure the response of the LT1394 requires
an input signal source with very fast rise times and
exceptionally clean settling characteristics. The last
requirement comes about because the standard comparator test calls for an input step size that is large compared
to the overdrive amplitude. Typical test conditions are
100mV step size with 5mV overdrive. This requires an
input signal that settles to within 1% (1mV) of final value
in only a few nanoseconds with no ringing or settling tail.
Ordinary high speed pulse generators are not capable of
generating such a signal, and in any case, no ordinary
oscilloscope is capable of displaying the waveform to
check its fidelity. Some means must be used to inherently
generate a fast, clean edge with known final value. The
circuit shown in Figure 2 is the best electronic means of
generating a fast, clean step to test comparators. It uses
a very fast transistor in a common base configuration. The
transistor is switched off with a fast edge from the generator and the collector voltage settles to exactly 0V in just a
few nanoseconds. The most important feature of this
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APPLICATIONS INFORMATION
5V
0.01µF*
0V
25Ω
–100mV
25Ω
0.1µF
+
2N3866
10k
V1**
–
Q
0.01µF
50Ω
0V
–3V
FET PROBE
LT1394
130Ω
PULSE
IN
Q
FET PROBE
* TOTAL LEAD LENGTH INCLUDING DEVICE PIN.
SOCKET AND CAPACITOR LEADS SHOULD BE
LESS THAN 0.5 IN. USE GROUND PLANE
** (VOS + OVERDRIVE)/200
50Ω
400Ω
750Ω
–5V
1394 F02
–5V
Figure 2. Response Time Test Circuit
circuit is the lack of feedthrough from the generator to the
comparator input. This prevents overshoot on the comparator input, which would give a false fast reading on
comparator response time.
To adjust the circuit for exactly 5mV overdrive, V1 is
adjusted so that the LT1394 output under test settles to
1.4V (in the linear region). Then V1 is changed by – 1V to
set overdrive to 5mV.
High Speed Design Techniques
A substantial amount of design effort has made the LT1394
relatively easy to use. It is much less prone to oscillation
than some slower comparators, even with slow input
signals. However, as with any high speed comparator,
there are a number of pitfalls which may arise because of
PC board layout and design. The most common problems
involve power supply bypassing. Bypassing is necessary
to maintain low supply impedance. DC resistance and
inductance in supply wires and PC traces can quickly build
up to unacceptable levels. This allows the supply line to
move with changing internal current levels of the connected devices. This will almost always result in improper
operation. In addition, adjacent devices connected through
an unbypassed supply can interact with each other through
the finite supply impedances. Bypass capacitors furnish a
simple solution to this problem by providing a local
reservoir of energy at the device, keeping supply impedances low.
Bypass capacitors should be as close as possible to the
LT1394. A good high frequency capacitor such as a 0.1µF
8
ceramic is recommended, in parallel with a larger capacitor such as a 4.7µF tantalum.
Poor trace routes and high source impedances are also
common sources of problems. Be sure to keep trace
lengths as short as possible, and avoid running any output
trace adjacent to an input trace to prevent unnecessary
coupling. If output traces are longer than a few inches, be
sure to terminate them with a resistor to eliminate any
reflections that may occur. Resistor values are typically
250Ω to 400Ω. Also, be sure to keep source impedances
as low as possible, preferably 1kΩ or less.
Crystal Oscillators
Figure 3’s circuits are crystal oscillators. In the circuit (a)
the resistors at the LT1394’s positive input set a DC bias
point. The 2k-0.068µF path sets up phase shifted feedback
and the circuit looks like a wideband unity-gain follower at
DC. The crystal’s path provides resonant positive feedback and stable oscillation occurs. The circuit (b) is
similar, but supports oscillation frequencies to 30MHz.
Above 10MHz, AT-cut crystals operate in overtone mode.
Because of this, oscillation can occur at multiples of the
desired frequency. The damper network rolls off gain at
high frequency, ensuring proper operation.
Switchable Output Crystal Oscillator
Figure 4 permits crystals to be electronically switched by
logic commands. This circuit is similar to the previous
examples, except that oscillation is only possible when
one of the logic inputs is biased high.
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APPLICATIONS INFORMATION
Temperature-Compensated Crystal Oscillator (TXCO)
5V
1MHz TO 10MHz
CRYSTAL (AT-CUT)
2k
Figure 5 is a temperature-compensated crystal oscillator
(TXCO). This circuit reduces oscillator temperature drift
by inserting a temperature-dependent compensatory correction into the crystal’s frequency trimming network.
This open-loop correction technique relies on cancellation
of the temperature characteristics of the oscillator, which
are quite repeatable.
+
(a)
OUTPUT
LT1394
2k
–
2k
0.068µF
10MHz TO 25MHz
CRYSTAL (AT-CUT)
5V
2k
22Ω
(b)
820pF
+
OUTPUT
LT1394
2k
–
2k
200pF
1394 F03
Figure 3. Crystal Oscillators for Outputs to 30MHz. Circuit (b)’s
Damper Network Supresses Overtone Crystal’s Harmonic Modes
XTAL X
RX
XTAL B
DX
LOGIC INPUTS
AS MANY STAGES
AS DESIRED
1k
B
5V
XTAL A
1k
18ns, 500µV Sensitivity Comparator
A
1k
D1
+
D2
OUTPUT
LT1394
1k
–
2k
75pF
= 1N4148
GROUND XTAL CASES
The LT1394 and associated components form the crystal
oscillator, operating similarly to Figure 3’s examples. The
LM134, a temperature-dependent current source, biases
A1. A1 takes gain referred to the LM134’s output and the
negative offset supplied via the 470kΩ-LT1004 reference
path. Note that the LT1004’s negative voltage bias is
bootstrapped from the oscillator’s output, maintaining
single supply operation. This arrangement delivers temperature-dependent bias to the varactor diode, causing a
scaled variation in the crystal’s resonance versus ambient
temperature. The varactor’s bias-dependent capacitance
shift pulls crystal frequency to complement the circuit’s
temperature drift. The simple first order fit provided by the
compensation is very effective. Figure 6 shows results.
The –70ppm frequency shift over 0°C to 70°C is corrected
within a few ppm. The “FREQ SET” trim also biases the
varactor, allowing accurate output frequency setting. It is
worth noting that better compensation is possible by
including higher order terms in the temperature-to-voltage conversion.
1394 F04
Figure 4. Switchable Output Crystal Oscillator. Biasing A or B
High Places Associated Crystal in Feedback Path. Additional
Crystal Branches Are Permissible
The ultimate limitation on comparator sensitivity is available gain. Unfortunately, increasing gain invariably
involves giving up speed. The gain vs. speed trade-off in a
fast comparator is usually a practical compromise
designed to satisfy most applications. Some situations,
however, require more sensitivity (e.g., higher gain) with
minimal impact on speed. Figure 7’s circuit adds a differential preamplifier ahead of the LT1394, increasing gain.
This permits 500µV comparisons in 18ns. A parallel path
DC stabilization approach eliminates preamplifier drift as
an error source. A1 is the differential preamplifier, operating at a gain of 100. Its output is AC-coupled to the LT1394.
9
LT1394
U
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APPLICATIONS INFORMATION
5.8M*
LM134
A1
LT1077
2M
226Ω*
1M*
+
MV-209
VARACTOR
DIODE
1M*
–
2M
1µF
5V
10mV/°C
10k*
470k*
10M
0.01µF
10MHz
2k
10MHz
0.05ppm/°C
+
5V
390Ω
LT1394
0.01µF
BAT-85
50k
–
100k
2k
1µF
4.7k
LT1004-1.2
+
0.068µF
1M
FREQ SET
1394 F05
XTAL AT-CUT, 35° 25′ ANGLE
* 1% FILM RESISTOR
Figure 5. Temperature-Compensated 10MHz Crystal Oscillator.
Temperature-Dependent Varactor Bias Reduces Drift by 20:1
5V
+
0
FREQUENCY DEVIATION (ppm)
A2
1/2 LT1126
200pF
COMPENSATED
≈ 0.05ppm/°C
–10
–
2k
10k
–20
–30
200Ω
–40
–50
10k
–
UNCOMPENSATED
(VARACTOR CORRECTION
DISABLED) –1ppm/°C
–60
A3
1/2 LT1126
+
–70
0
10
40
30
50
20
TEMPERATURE (°C)
60
70
–5V
2k
200pF
1394 F06
Figure 6. Figure 5’s Compensated vs Uncompensated
Temperature Dependence. First Order Compensation
Reduces Oscillator Drift to 0.05ppm/°C
5V
+INPUT
–INPUT
+
+
1µF
1k
+
A1
LM733
–A = 100
–
LT1394
OUTPUT
–
1µF
–5V
1k
1394 F07
Figure 7. Parallel Preamplified Paths Allow 18ns Comparator
Response to 500µV Overdrive
10
LT1394
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APPLICATIONS INFORMATION
Figure 8 shows waveforms for the high gain comparator.
Trace A is a 500µV overdrive on a 1mV step applied to the
circuit’s positive input (negative input grounded). Trace B
shows the resulting amplified step at A1’s positive output.
Trace C is A2’s band limited output. A1’s wideband output
combines with A2’s DC corrected information to yield the
correct, amplified composite signal at the LT1394’s positive input in Trace D. The LT1394’s output is Trace E. Figure
9 details circuit propagation delay. The output responds in
18ns to a 500µV overdrive on a 1mV step. Figure 10 plots
response time versus overdrive. As might be expected,
propagation delay decreases at higher overdrives. A1’s
noise limits usable sensitivity.
1100
1000
OVERDRIVE (µV)
A1 has poorly defined DC characteristics, necessitating
some form of DC correction. A2 and A3, operating at a
differential gain of 100, provide this function. They differentially sense a band limited version of A1’s inputs and feed
DC and low frequency amplified information to the comparator. The low frequency roll-off of A1’s signal path
complements A2-A3’s high frequency roll-off. The summation of these two signal channels at the LT1394 inputs
results in flat response from DC to high frequency.
900
800
700
600
500
A = 1mV/DIV
15
16
17
RESPONSE TIME (ns)
18
1394 F10
B = 0.1V/DIV
(AC-COUPLED)
Figure 10. Response Time vs Overdrive for the
Composite Comparator
C = 0.1V/DIV
D = 0.1V/DIV
Voltage-Controlled Delay
E = 5V/DIV
5µs/DIV
1394 F08
Figure 8. 500µV Input (Trace A) Is Split into Wideband
and Low Frequency Gain Paths (Traces B and C) and
Recombined (Trace D). Comparator Output Is Trace E
A = 1mV/DIV
B = 1V/DIV
10ns/DIV
1394 F09
Figure 9. Parallel Path Comparator Shows 18ns
Response (Trace B) to 500µV Overdrive (Trace A)
The ability to set a precise, predictable delay has broad
application in pulse circuitry. Figure 11’s configuration
sets a 0 to 300ns delay from a corresponding 0V to 3V
control voltage. It takes advantage of the LT1394’s speed
and the clean dynamics of an emitter switched current
source.
Q1 and Q2 form a current source that charges the 1000pF
capacitor. When the trigger input is high (Trace A, Figure
12) both Q3 and Q4 are on. The current source is off and
Q2’s collector (Trace B) is at ground. The latch input at the
LT1394 prevents it from responding and its output remains
high. When the trigger input goes low, the LT1394’s latch
input is disabled and its output drops low. Q4’s collector
(Trace C) lifts and Q2 comes on, delivering constant
current to the 1000pF capacitor (Trace B). The resulting
linear ramp at the LT1394’s positive input is compared to
the delay programming voltage input. When a crossing
occurs, the comparator goes high (Trace D). The length of
time the comparator was low is directly proportional to the
11
LT1394
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APPLICATIONS INFORMATION
5V
DELAY PROGRAMMING
VOLTAGE INPUT
0V TO 3V = 0 TO 300ns DELAY
A = 5V/DIV
0.1µF
LT1634
100Ω
B = 2V/DIV
1k
100Ω
(DELAY
CALIB)
C = 5V/DIV
51pF
0.1µF
D = 5V/DIV
330Ω
Q2 Q4
Q1
100ns/DIV
–
LT1394
+
1000pF
Q OUTPUT
Q OUTPUT
330Ω
Q3
220Ω
TRIGGER INPUT
200ns MINIMUM
Figure 12. Voltage-Controlled Delay’s Waveforms.
Programming Voltage Determines Delay Between Input
(Trace A) Falling Edge and Output (Trace D) Rising Edge.
High Linearity Timing Ramp (Trace B) Permits 1ns
Accuracy and 100ps Repeatability
1394 F11
PNP = 2N5087
NPN = 2N2369
Figure 11. Fast, Precise, Voltage-Controlled Delay.
Emitter Switched Current Source Has Clean,
Predictable Dynamics
delay programming voltage. The fast switching and ramp
linearity permits 1ns accuracy and 100ps repeatability.
Figure 13, a high speed expansion of the current source
turn-on, details the clean switching. Q4 goes off within 2ns
of the trigger input (Trace A) dropping low, enabling the
current source (Q2’s emitter is Trace C). Concurrently, the
1000pF capacitor’s ramp (Trace B) begins. The LT1394’s
output (Trace D) drops low about 7ns later, returning high
after crossing (in this case) a relatively low programming
voltage. Figure 14 juxtaposes the waveforms differently,
permitting enhanced study of circuit timing. Switching
begins with the input trigger falling low (Trace A). The ramp
(Trace C) begins 3ns after the current source turns on (Q2
emitter is Trace D). The output pulse (Trace B) begins
about 4ns later.
To calibrate this circuit apply a trigger input and 3V to the
programming input. Adjust the 100Ω trim for a 300ns
width at the LT1394’s output.
12
1394 F12
A = 2V/DIV
B = 0.1V/DIV
C = 2V/DIV
D = 2V/DIV
10ns/DIV
1394 F13
Figure 13. High Speed Expansion of Figure 12. Ramp
(Trace B) Begins When Trigger (Trace A) Falls and
Current Source Turns On (Trace C). Trace D is Output
A = 1V/DIV
B = 1V/DIV
C = 0.1V/DIV
D = 1V/DIV
10ns/DIV
1394 F14
Figure 14. Delay’s Output Switching Begins with
Trigger Falling Low (Trace A). Ramp (Trace C) Starts
3ns After Current Source Turn-On (Trace D). Output
(Trace B) Begins 4ns Later
LT1394
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APPLICATIONS INFORMATION
Fast, High Impedance, Variable Threshold Trigger
A frequent requirement in instrumentation is a fast trigger
with a variable threshold. Often, a high impedance input is
also required. Figure 15 meets these requirements. Comparator C1 is the basic trigger, with threshold voltage set at
its negative input. Source follower Q1 provides high
impedance with about 2pF input capacitance and 50pA bias
current. Normally, Q1’s source bias point would be uncertain and drifty, but stabilization techniques eliminate this
concern. A1 measures filtered versions of Q1’s gate and
source voltages. A1’s output biases Q2, forcing Q1’s
channel current to whatever value is required to equalize
A1’s inputs, and hence Q1’s gate and source voltages. A1’s
input filtering and roll-off are far slower than input frequencies of interest; its action does not interfere with the
circuit’s main signal path. The 330pF capacitor prevents
fast edges coupled through Q2’s collector base junction
from influencing A1’s operation.
Q1 should contribute negligible timing error to minimize
overall delay. Figure 16’s photo verifies Q1’s wideband
operation. Trace B, Q1’s source, lags the input (Trace A) by
only 300ps. Input, FET buffer output and C1 output appear
as Traces A, B and C, respectively in Figure 17. As before,
the FET buffer is seen to contribute small timing error, and
C1’s output is about 8ns delayed from the input.
A = 1V/DIV
B = 1V/DIV
200ps/DIV
Figure 16. Trigger Buffer’s 300ps Delay Minimizes
Timing Error. 4GHz Sampling Oscilloscope’s Output Is
a Series of Dots
VTRIG
±3V
5V
1394 F16
–
C1
LT1394
Q1
2N5486
INPUT
±3V
OUTPUT
+
10M
10M
0.01µF
Q2
2N3904
1.5k
–
10k
C = 2V/DIV
A1
LT1097
+
100Ω
–5V
330pF
A = 1V/DIV
B = 1V/DIV
0.1µF
0.1µF
10ns/DIV
1394 F17
1394 F15
Figure 15. Buffer Provides 2pF, 50pA Input Characteristics for
Fast Trigger. Amplifier-Stabilized Biasing Eliminates FET Offset
Figure 17. Input (Trace A), FET Source (Trace B)
and Output (Trace C) Waveforms for the Trigger.
Total Delay Is 8ns
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LT1394
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APPLICATIONS INFORMATION
High Speed Adaptive Trigger Circuit
Line and fibre-optic receivers often require an adaptive
trigger to compensate for variations in signal amplitude
and DC offsets. The circuit in Figure 18 triggers on 2mV to
175mV signals from 100Hz to 45MHz while operating from
a single 5V rail. A1, operating at a gain of 15, provides
wideband AC gain. The output of this stage biases a 2-way
peak detector (Q1 through Q4). The maximum peak is
stored in Q2’s emitter capacitor, while the minimum excursion is retained in Q4’s emitter capacitor. The DC value of
the midpoint of A1’s output signal appears at the junction
of the 500pF capacitor and the 3MΩ units. This point
always sits midway between the signal’s excursions,
egardless of absolute amplitude. This signal-adaptive voltage is buffered by A2 to set the trigger voltage at the
LT1394’s positive input. The LT1394’s negative input is
biased directly from A1’s output. The LT1394’s output, the
circuit’s output, is unaffected by >85:1 signal amplitude
variations. Bandwidth limiting in A1 does not affect triggering because the adaptive trigger threshold varies
ratiometrically to maintain circuit output.
1
5
510Ω
15
A2
LT1006
Q1, Q2, Q3, Q4 = CA3096 ARRAY:
TIE SUBSTRATE (PIN 16) TO GROUND
= 1N4148
3M
10
14 12
Q3
Q4
11
470Ω
+
+
0.1µF
5V
+
–
36Ω
AN72 F64
Figure 19. Adaptive Trigger Responding to a 40MHz,
5mV Input. Input Amplitude Variations from 2mV to
175mV Are Accommodated
0.005µF
5V
10µF +
50ns/DIV
500pF
0.005µF
13
750Ω
C = 5V/DIV
3M
–
2k
B = 0.1V/DIV
Q2
4
2
A1
LT1227
A = 0.1V/DIV
6
3
Q1
+
Split supply versions of this circuit can achieve bandwidths to 50MHz with wider input operating range.
5V
2k
5V
Figure 19 shows operating waveforms at 45MHz. Trace A’s
input produces Trace B’s amplified output at A1. The
comparator’s output is Trace C.
100µF
0.1µF
2k
470Ω
0.1µF
–
LT1394
TRIGGER
OUT
INPUT
1394 F18
Figure 18. 45MHz Single Supply Adaptive Trigger. Output Comparator’s
Threshold Varies Ratiometrically with Input Amplitude, Maintaining Data
Integrity over > 85:1 Input Amplitude Range
14
LT1394
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PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
MS8 Package
8-Lead Plastic MSOP
(LTC DWG # 05-08-1660)
0.118 ± 0.004*
(3.00 ± 0.102)
8
7 6
5
0.118 ± 0.004**
(3.00 ± 0.102)
0.192 ± 0.004
(4.88 ± 0.10)
1
2 3
4
0.040 ± 0.006
(1.02 ± 0.15)
0.007
(0.18)
0.034 ± 0.004
(0.86 ± 0.102)
0° – 6° TYP
0.021 ± 0.006
(0.53 ± 0.015)
SEATING
PLANE 0.012
(0.30)
0.0256
REF
(0.65)
TYP
0.006 ± 0.004
(0.15 ± 0.102)
MSOP (MS8) 1197
* DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS. MOLD FLASH,
PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
S8 Package
8-Lead Plastic Small Outline (Narrow 0.150)
(LTC DWG # 05-08-1610)
0.189 – 0.197*
(4.801 – 5.004)
8
7
6
5
0.150 – 0.157**
(3.810 – 3.988)
0.228 – 0.244
(5.791 – 6.197)
1
0.010 – 0.020
× 45°
(0.254 – 0.508)
0.008 – 0.010
(0.203 – 0.254)
0.053 – 0.069
(1.346 – 1.752)
0°– 8° TYP
0.016 – 0.050
0.406 – 1.270
0.014 – 0.019
(0.355 – 0.483)
2
3
4
0.004 – 0.010
(0.101 – 0.254)
0.050
(1.270)
TYP
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
SO8 0996
15
LT1394
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TYPICAL APPLICATION
9
Voltage-Controlled Crystal Oscillator (VCXO)
14.3217MHz
8
FREQUENCY DEVIATION (kHz)
Figure 20, a variant of the basic crystal oscillator, permits
voltage tuning the output frequency. Such voltage-controlled crystal oscillators (VCXO) are often employed
where slight variation of a stable carrier is required. This
example is specifically intended to provide a 4 × NTSC
sub-carrier tunable oscillator suitable for phase locking.
The LT1394 is set up as a crystal oscillator, operating
similarly to Figure 3 (a). The varactor diode is biased from
the tuning input. The tuning network is arranged so a 0V
to 5V drive provides a reasonably symmetric, broad tuning
range around the 14.31818MHz center frequency. The
indicated selected capacitor sets tuning bandwidth. It
should be picked to complement loop response in phase
locking applications. Figure 21 is a plot of tuning input
voltage versus frequency deviation. Tuning deviation from
the 4 × NTSC 14.31818MHz center frequency exceeds
±240ppm for a 0V to 5V input.
7
6
5
14.31818MHz
4
3
2
1
14.314.0MHz
0
0
1
3
2
INPUT VOLTAGE (V)
5
4
1394 F21
Figure 21. Control Voltage vs Output Frequency for Figure 15.
Tuning Deviation from Center Frequency Exceeds ±240ppm
5V
1N4148
C SELECT***
0.047µF
1M
1M
5V
2k
MV-209†
1M*
47k*
3.9k*
LT1004-2.5
VIN
0V TO 5V
1k*
1M
100pF
390Ω
+
Y1** 15pF
100pF
LT1394
–
2k
200pF
FREQUENCY
OUTPUT
* 1% FILM RESISTOR
** NORTHERN ENGINEERING LABS C-2350N-14.31818MHz
*** C SELECT SETS TUNING BANDWIDTH. SET TO COMPLEMENT
LOOP RESPONSE IN PHASE LOCKING APPLICATIONS
† VARACTOR DIODE
1394 F20
Figure 20. A 4× NTSC Sub-Carrier Voltage-Tunable Crystal Oscillator. Tuning Range
and Bandwidth Accommodate Variety of Phase Locked Loops
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1016
UltraFast Precision Comparator
Industry Standard 10ns Comparator
LT1116
12ns Single Supply Ground-Sensing Comparator
Single Supply Version of LT1016
LT1671
Fast Single Supply Comparator
60ns, 450µA Single Supply Comparator
LT1720
UltraFast Dual Single Supply Comparator
Dual 4.5ns, 4mA Single Supply Comparator
16
Linear Technology Corporation
1394f LT/TP 0499 4K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 1998
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