AD9300 데이터 시트보기 (PDF) - Analog Devices
부품명
상세내역
제조사
AD9300 Datasheet PDF : 8 Pages
| |||
AD9300
THEORY OF OPERATION
Refer to the functional block diagram of the AD9300.
As shown in the drawing, this diagram is based on the pinouts of
the DIP packaging of the models AD9300KQ and AD9300TQ.
The AD9300KP and AD9300TE are packaged in 20-pin surface
mount packages. The extra pins are used for ground connections;
the theory of operation remains the same.
The AD9300 Video Multiplexer allows the user to connect any
one of four analog input channels (IN1–IN4) to the output of the
device and to switch between channels at megahertz rates.
The input channel, which is connected to the output is deter-
mined by a 2-bit TTL digital code applied to A0 and A1. The se-
lected input will not appear at the output unless a digital “1” is
also applied to the ENABLE input pin; unless the output is
enabled, it is a high impedance. Necessary combinations to ac-
complish channel selection are shown in the Logic Truth Table.
Figure 1. Input and Output Equivalent Circuits
Bipolar construction used in the AD9300 ensures that the input
impedance of the device remains high and will not vary with
power supply voltages. This characteristic makes the AD9300,
in effect, a switchable-input buffer. An onboard bias network
makes the performance of the AD9300 independent of applied
supply voltages, which can have any nominal value from
± 10 V dc to ± 15 V dc.
Although the primary application for the AD9300 is the routing
of video signals, the harmonic and dynamic attributes of the
device make it appropriate for other applications. The AD9300
has exceptional performance when switching video signals and
can also be used for switching other analog signals requiring
greater dynamic range and/or precision than those in video.
As shown in Figure 1, each analog input is connected to the
base of a bipolar transistor. If Channel 1 is selected, a current
switch is closed and routes current through the input transistor
for Channel 1.
If Channel 2 is then selected by the digital inputs, the current
switch for Channel 1 is opened and the current switch for Chan-
nel 2 is closed. This causes current to be routed away from the
Channel 1 transistor and into the Channel 2 input transistor.
Whenever a channel’s input device is carrying current, the ana-
log input applied to that channel is passed to the output stage.
The operation of the output stage is similar to that of the input
stages. Whenever the output stage is enabled with a HIGH digi-
tal “1” signal at the ENABLE pin, the output transistor will
carry current and pass the selected analog input.
When the output stage is disabled (by virtue of the ENABLE
pin being driven LOW with a digital “0”), the output current
switch is opened. This routes the current to other circuits within
the AD9300 that keep the output transistor biased “off.” These
circuits require approximately 1 µA of bias current from the load
connected to the output of the multiplexer. In the absence of a
terminating load and the resulting dc bias, the output of the
AD9300 “floats” at –2.5 V.
In summary, when the AD9300 is enabled by the ENABLE pin
being driven HIGH with a digital “1,” the selected analog input
channel acts as a buffer for the input and the output of the mul-
tiplexer is a low impedance. When the AD9300 is disabled with
a digital “0” LOW signal, the selected channel acts as an open
switch for the input, and the output of the unit becomes a high
impedance. This characteristic allows the user to wire-or several
AD9300 Analog Multiplexers together to form switch matrices.
REV. A
–5–
Share Link: 