CLC446 National Semiconductor, CLC446 Datasheet
CLC446
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CLC446 Summary of contents
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... The CLC446 achieves its superior speed- vs-power using an advanced complementary bipolar IC process and National’s current-feedback architecture. The CLC446 is designed to drive video loads with very low differential gain and phase errors (0.02%, 0.03°). Combined with its very low power (50mW), the CLC446 makes an excellent choice for NTSC/PAL video switchers and routers ...
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... Model ±48mA CLC446AJP ±Vcc CLC446AJE +175 ˚ C CLC446ALC CLC446A8B -65 ˚ +150 ˚ C CLC446AMC +300 ˚ C Contact the factory for other packages and DESC SMD number. 1000V Package Thermal Resistance Package Plastic (AJP) Surface Mount (AJE) Ceramic (A8B) Transistor Count ...
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Typical Performance Characteristics Non-Inverting Frequency Response 453 249 10V 200 -180 f -270 A ...
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... Short Term Settling Time 0.2 0.1 0 -0.1 -0.2 1n 10n The CLC446 has a current-feedback architecture built in an advanced complementary bipolar process. The key features of current-feedback are: AC bandwidth is independent of voltage gain Unity-gain stability Frequency response may be adjusted with R High slew rate Low variation in performance for a wide range ...
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... ref Figure 4: Level Shifting Circuit and R 1 and C . The coupling capac isolates its DC bias point CLC446 Figure 5: Single Supply Circuit http://www ...
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... V is the peak output sinusoidal voltage. peak http://www.national.com The slew rate of the CLC446 in inverting gains is always higher than in non-inverting gains. AC Design (linear phase/constant group delay) The recommended value of R peaking and a reasonably linear phase response. To improve phase linearity when |A approximately 50% over its recommended value ...
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... Figure (NF). This allows the calculation of signal to noise . o ratio into a defined load. Figure 8 plots the NF for a CLC446 at a gain of 10, and with a feedback resistor R of 100 . The minimum NF (3.9dB) occurs when the source impedance equals 1600 . and load Figure 8: Noise Figure vs. Source Resistance = 175 – ...
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... The CLC446 noise model in Figure 9 is used to develop this equation for NF 10log where the source resistance at the non- S inverting input There is no matching resistor from the input to ground and i ...
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... The Typical Application depicted on the front page is a 10MHz, third-order elliptic filter. It has a voltage- controlled, voltage source (VCVS) topology using a CLC446. To calculate the component values for this filter, do the following: 1. Select the filter approximation function for your application (see References [1-2]). For this design ...
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Figure 12 shows the ideal response of this filter. Some methods to bring actual performance closer to this ideal are: Compensate for op amp delay effects (pre-distortion) Adjust for parasitic capacitances in the layout Use components with small tolerances Add ...
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... Customer Design Applications Support National Semiconductor is committed to design excellence. For sales, literature and technical support, call the National Semiconductor Customer Response Group at 1-800-272-9959 or fax 1-800-737-7018. Life Support Policy National’s products are not authorized for use as critical components in life support devices or systems without the express written approval of the president of National Semiconductor Corporation ...