Texas Instruments LMH7324 Quad 700ps High Speed Comparator with RSPECL Outputs Evaluation Board LMH7324EVAL/NOPB LMH7324EVAL/NOPB 데이터 시트
제품 코드
LMH7324EVAL/NOPB
Layout Considerations
Table 2. Truth Table
V
IN
Con1
Con3
Con4
High
0
1
1
In Window
1
0
1
Low
1
1
0
2.3
Outputs
Every output has a Q and Q connection and both outputs have been made active by a resistor connected
to the V
to the V
EE
terminal. An ECL output becomes active when current flows out of the emitters of the output
stage. This can be done by connecting a resistor to a ‘termination’ voltage (VT) which is 2V below the
V
V
CCO
. When using the VT solution every output resistor has to be 50
Ω
(R1, R2, R4, R5, R10, R11, R12).
Another possibility is to connect a resistor to the most negative supply voltage. In case of a connection to
V
V
EE
, the resistor must have a value which causes a current that complies with the ‘Normal Operating’
conditions as mentioned in the datasheet. This demo board is designed for a supply voltage of 5V for the
V
V
CCO
with a resistor to V
EE
with a value of 240
Ω
(R4 = 360 while R1, R2, R5, R10, R11, R12 = 240). In
case the V
CCO
is raised to 12V all output resistors to V
EE
should be replaced with 500
Ω
resistors except R4
which should be 750
Ω
. All three output signals are connected via a 50
Ω
track and a combined capacitor
and jumper which are connected in parallel. A customer can now make a choice between a DC or an AC
coupled output signal. In the case of a DC coupled output be aware of the offset voltage which causes an
extra DC current into a connected scope or analyzer with 50
coupled output signal. In the case of a DC coupled output be aware of the offset voltage which causes an
extra DC current into a connected scope or analyzer with 50
Ω
input impedance.
2.4
Supply Voltages
This demo board can operate with a simple dual supply of ±2.5V. The output voltages are now about
1.35V and 1.0V and comply with LVDS and RSPECL levels. In the case of a single supply voltage of +5V
the output levels are 3.85V and 3.5V, which is only RSPECL level compliant. In a single supply
configuration be aware that the detection window starts at V
1.35V and 1.0V and comply with LVDS and RSPECL levels. In the case of a single supply voltage of +5V
the output levels are 3.85V and 3.5V, which is only RSPECL level compliant. In a single supply
configuration be aware that the detection window starts at V
EE
level, which is actually the ground level.
The LMH7324 is ground sensing but in this configuration the input signals cannot extend more than 200
mV below the ground level. Every comparator has a separate connection for the V
mV below the ground level. Every comparator has a separate connection for the V
CCI
, V
CCO
and the V
EE
.
The supply pins are decoupled with a small capacitance of 10 nF to the ground plane. Since the outputs
are referenced to the V
are referenced to the V
CCO
the output resistors are decoupled to this supply pin. For better low frequency
decoupling a 47 µF capacitor is placed at the supply connector (con5). The supplies V
CCI
and V
CCO
can be
shortened by a jumper (J1) in case both positive supply voltages are the same value.
3
Layout Considerations
The layout is done with a four layer board which makes it easy to keep the design compact with small 50
Ω
tracks. The advantage of this is that such tracks route easily and connect perfectly to small components.
At the same time the length and number of supply lines are reduced, while decoupling to these supplies is
easy and direct. Signals are routed on the top and bottom layer, making it easy to measure them.
At the same time the length and number of supply lines are reduced, while decoupling to these supplies is
easy and direct. Signals are routed on the top and bottom layer, making it easy to measure them.
4
Measurement Hints and Results
Measurements can be done at the output connectors by connecting a scope or analyzer to the test board.
The outputs are capable of driving a 50
The outputs are capable of driving a 50
Ω
load. This board offers the possibility of making the output DC or
AC coupled. When DC coupling is used be aware of the DC offset voltage present on the output signals.
When working with a high supply voltage on the V
When working with a high supply voltage on the V
CCO
it is possible to damage the output stage of the
device or the input impedance of the equipment. To show what signals can be expected sample
measurement results are shown in the following figures. Measurements were taken at different
frequencies and waveforms. In the first instance measurements were taken at a frequency of 5 MHz with a
sawtooth waveform. The supply voltages are +2.5V and –2.5V. This means that both thresholds are at the
same level of approximately 50 mV. There are three results shown: one with the input signal crossing only
the upper level (see
measurement results are shown in the following figures. Measurements were taken at different
frequencies and waveforms. In the first instance measurements were taken at a frequency of 5 MHz with a
sawtooth waveform. The supply voltages are +2.5V and –2.5V. This means that both thresholds are at the
same level of approximately 50 mV. There are three results shown: one with the input signal crossing only
the upper level (see
) and one while the input signal is only crossing the lowest level (see
). The third plot shows the waveforms when the input signal crosses the complete window from
below the lowest level until above the upper level (see
).
2
AN-1683 LMH7324 High Speed Comparator Evaluation Board
SNOA494A – September 2007 – Revised May 2013
Copyright © 2007–2013, Texas Instruments Incorporated