LTC1569-6 Linear Phase, DC Accurate, Low Power, 10th Order Lowpass Filter FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ One External R Sets Cutoff Frequency Root Raised Cosine Response 3mA Supply Current with a Single 3V Supply Up to 64kHz Cutoff on a Single 3V Supply 10th Order, Linear Phase Filter in an SO-8 DC Accurate, VOS(MAX) = 5mV Low Power Modes Differential or Single-Ended Inputs 80dB CMRR (DC) 82dB Signal-to-Noise Ratio, VS = 5V Operates from 3V to ±5V Supplies U APPLICATIO S ■ ■ ■ Data Communication Filters for 3V Operation Linear Phase and Phase Matched Filters for I/Q Signal Processing Pin Programmable Cutoff Frequency Lowpass Filters U DESCRIPTIO The LTC®1569-6 is a 10th order lowpass filter featuring linear phase and a root raised cosine amplitude response. The high selectivity of the LTC1569-6 combined with its linear phase in the passband makes it suitable for filtering both in data communications and data acquisition sys- tems. Furthermore, its root raised cosine response offers the optimum pulse shaping for PAM data communications. The filter attenuation is 50dB at 1.5 • fCUTOFF, 60dB at 2 • fCUTOFF, and in excess of 80dB at 6 • fCUTOFF. DCaccuracy-sensitive applications benefit from the 5mV maximum DC offset. The LTC1569-6 sampled data filter does not require an external clock yet its cutoff frequency can be set with a single external resistor with a typical accuracy of 3.5% or better. The external resistor programs an internal oscillator whose frequency is divided by either 1, 4 or 16 prior to being applied to the filter network. Pin 5 determines the divider setting. Thus, up to three cutoff frequencies can be obtained for each external resistor value. Using various resistor values and divider settings, the cutoff frequency can be programmed over a range of six octaves. Alternatively, the cutoff frequency can be set with an external clock and the clock-to-cutoff frequency ratio is 64:1. The ratio of the internal sampling rate to the filter cutoff frequency is 128:1. The LTC1569-6 is fully tested for a cutoff frequency of 64kHz with a single 3V supply. The LTC1569-6 features power saving modes and it is available in an SO-8 surface mount package. , LTC and LT are registered trademarks of Linear Technology Corporation. U TYPICAL APPLICATIO Frequency Response, fCUTOFF = 64kHz/16kHz/4kHz 0 Single 3V Supply, 64kHz/16kHz/4kHz Lowpass Filter 3V 1 IN + OUT 2 IN – V+ 7 –20 VOUT REXT = 10k 3V 1µF LTC1569-6 3.48k 3 2k 8 GND RX 6 1µF V– DIV/CLK fCUTOFF = –80 1/1 100pF –100 64kHz (10k/REXT) 1, 4 OR 16 –60 1/4 5 EASY TO SET fCUTOFF: –40 3V 1/16 4 GAIN (dB) VIN 1569-6 TA01 1 10 100 FREQUENCY (kHz) 1000 1569-6 TA01a 1 LTC1569-6 U U RATI GS W W W W AXI U U ABSOLUTE PACKAGE/ORDER I FOR ATIO (Note 1) Total Supply Voltage ................................................ 11V Power Dissipation .............................................. 500mW Operating Temperature LTC1569C ............................................... 0°C to 70°C LTC1569I ............................................ – 40°C to 85°C Storage Temperature ............................ – 65°C to 150°C Lead Temperature (Soldering, 10 sec).................. 300°C ORDER PART NUMBER TOP VIEW IN + 1 8 OUT IN – 2 7 V+ GND 3 6 RX V– 4 5 DIV/CLK LTC1569CS8-6 LTC1569IS8-6 S8 PART MARKING S8 PACKAGE 8-LEAD PLASTIC SO TJMAX = 125°C, θJA = 150°C/W 15696 1569I6 Consult factory for Military grade parts. ELECTRICAL CHARACTERISTICS The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VS = 3V (V + = 3V, V – = 0V), fCUTOFF = 64kHz, RLOAD = 10k unless otherwise specified. PARAMETER CONDITIONS MIN TYP MAX UNITS Filter Gain VS = 5V, fCLK = 4.096MHz, fCUTOFF = 64kHz, VIN = 1.4VP-P, REXT = 10k, Pin 5 Shorted to Pin 4 fIN = 1280Hz = 0.02 • fCUTOFF fIN = 12.8kHz = 0.2 • fCUTOFF fIN = 32kHz = 0.5 • fCUTOFF fIN = 51.2kHz = 0.8 • fCUTOFF fIN = 64kHz = fCUTOFF fIN = 97.5kHz = 1.5 • fCUTOFF (LTC1569I) fIN = 97.5kHz = 1.5 • fCUTOFF (LTC1569C) fIN = 128kHz = 2 • fCUTOFF fIN = 192kHz = 3 • fCUTOFF ● ● ● ● ● ● ● ● ● –0.05 – 0.25 – 0.65 – 1.3 – 5.3 0.05 – 0.15 – 0.55 – 1.0 – 3.8 – 60 – 60 – 62 – 71 0.15 – 0.05 – 0.4 – 0.7 – 2.4 – 40 – 48 – 50 – 60 dB dB dB dB dB dB dB dB dB VS = 2.7V, fCLK = 1MHz, fCUTOFF = 15.625kHz, VIN = 1VP-P, Pin 6 Shorted to Pin 4, External Clock fIN = 312Hz = 0.02 • fCUTOFF fIN = 3125kHz = 0.2 • fCUTOFF fIN = 7812kHz = 0.5 • fCUTOFF fIN = 12.5kHz = 0.8 • fCUTOFF fIN = 15.625kHz = fCUTOFF fIN = 23.44kHz = 1.5 • fCUTOFF (LTC1569I) fIN = 23.44kHz = 1.5 • fCUTOFF (LTC1569C) fIN = 31.25kHz = 2 • fCUTOFF (LTC1569I) fIN = 31.25kHz = 2 • fCUTOFF (LTC1569C) fIN = 46.88kHz = 3 • fCUTOFF ● ● ● ● ● ● ● ● ● ● – 0.12 – 0.25 – 0.65 – 1.1 – 3.6 0.05 – 0.15 – 0.55 – 0.9 – 3.4 – 54 – 54 – 60 – 60 – 66 0.16 – 0.05 – 0.4 – 0.7 – 3.2 – 48 – 50 – 52 – 55 – 60 dB dB dB dB dB dB dB dB dB dB VS = 2.7V, fCLK = 4MHz, fCUTOFF = 62.5kHz, Pin 6 Shorted to Pin 4, External Clock fIN = 1250Hz = 0.02 • fCUTOFF fIN = 12.5kHz = 0.2 • fCUTOFF fIN = 31.25kHz = 0.5 • fCUTOFF fIN = 50kHz = 0.8 • fCUTOFF fIN = 62.5kHz = fCUTOFF fIN = 93.75kHz = 1.5 • fCUTOFF ● ● ● ● – 114 79 – 83 156 –11 – 111 82 – 79 162 – 91 –108 85 – 75 168 Deg Deg Deg Deg Deg Deg Filter Phase Filter Cutoff Accuracy when Self-Clocked REXT = 10.24k from Pin 6 to Pin 7, VS = 3V, Pin 5 Shorted to Pin 4 Filter Output DC Swing (Note 6) VS = 3V, Pin 3 = 1.11V 62.5kHz ±1% ● 1.9 ● 3.7 VS = 5V, Pin 3 = 2V VS = ±5V, Pin 5 Shorted to Pin 7, RLOAD = 20k 2 2.1 VP-P VP-P 3.9 VP-P VP-P 8.5 VP-P LTC1569-6 ELECTRICAL CHARACTERISTICS The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VS = 3V (V + = 3V, V – = 0V), fCLK = 4.096MHz, fCUTOFF = 64kHz, RLOAD = 10k unless otherwise specified. PARAMETER CONDITIONS Output DC Offset (Note 2) REXT = 10k, Pin 5 Shorted to Pin 7 Output DC Offset Drift Clock Pin Logic Thresholds when Clocked Externally Power Supply Current (Note 3) MIN TYP MAX UNITS VS = 3V VS = 5V VS = ±5V ±2 ±6 ±15 ±5 ±12 mV mV mV REXT = 10k, Pin 5 Shorted to Pin 7 VS = 3V VS = 5V VS = ±5V 25 25 75 µV/°C µV/°C µV/°C VS = 3V Min Logical “1” Max Logical “0” 2.7 0.5 V V VS = 5V Min Logical “1” Max Logical “0” 4.0 0.5 V V VS = ±5V Min Logical “1” Max Logical “0” 4.0 0.5 V V fCLK = 256kHz (40k from Pin 6 to Pin 7, Pin 5 Open, ÷ 4), fCUTOFF = 4kHz VS = 3V 3 4 5 mA mA 3.5 5 6 mA mA 4.5 7 8 mA mA ● VS = 5V ● VS = 10V ● fCLK = 4.096MHz (10k from Pin 6 to Pin 7, Pin 5 Shorted to Pin 4, ÷ 1), fCUTOFF = 64kHz VS = 3V 8 VS = 5V 13 mA mA mA mA 17 mA mA 11 ● 9 ● VS = 10V 12 ● Clock Feedthrough Pin 5 Open 0.1 mVRMS Wideband Noise Noise BW = DC to 2 • fCUTOFF 95 µVRMS THD fIN = 3kHz, 1.5VP-P, fCUTOFF = 32kHz 80 dB Clock-to-Cutoff Frequency Ratio 64 Max Clock Frequency (Note 4) VS = 3V VS = 5V VS = ±5V Min Clock Frequency (Note 5) VS = 3V, 5V, TA < 85°C VS = ±5V Input Frequency Range Aliased Components <–65dB Note 1: Absolute maximum ratings are those values beyond which the life of a device may be impaired. Note 2: DC offset is measured with respect to Pin 3. Note 3: If the internal oscillator is used as the clock source and the divideby-4 or divide-by-16 mode is enabled, the supply current is reduced as much as 40% relative to the divide-by-1 mode. 5 5 7 MHz MHz MHz 1.5 3 kHz kHz 0.9 • fCLK Hz Note 4: The maximum clock frequency is arbitrarily defined as the frequency at which the filter AC response exhibits >1dB of gain peaking. Note 5: The minimum clock frequency is arbitrarily defined as the frequecy at which the filter DC offset changes by more than 5mV. Note 6: For more details refer to the Input and Output Voltage Range paragraph in the Applications Information section. 3 LTC1569-6 U W TYPICAL PERFOR A CE CHARACTERISTICS Passband Gain and Group Delay vs Frequency 1 40 –10 0 36 –30 –1 32 –2 28 –3 24 GAIN (dB) 10 –50 –70 –90 2.5 10 100 FREQUENCY (kHz) –4 0.2 1000 20 1 10 FREQUENCY (kHz) 80 1569-6 G01 1569-6 GO2 THD vs Input Frequency THD vs Input Voltage –50 –60 –55 –65 VS = 3V PIN 3 = 1.11V –60 THD (dB) THD (dB) VS = 5V PIN 3 = 2V –70 –75 –65 VS = 5V PIN 3 = 2V –70 –75 –80 –80 VIN = 1.5VP-P fCUTOFF = 32kHz IN + TO OUT –85 –90 DELAY (µs) GAIN (dB) Gain vs Frequency 0 5 fIN = 3kHz fCUTOFF = 32kHz IN + TO OUT –85 10 15 20 25 INPUT FREQUENCY (kHz) –90 30 0 0.5 1.0 1.5 2.0 2.5 3.0 INPUT VOLTAGE (VP-P) 1569-6 G03 3V Supply Current 11 9 10 8 9 4.0 1569-6 G04 ±5V Supply Current 5V Supply Current 10 3.5 14 12 EXT CLK 5 4 DIV-BY-16 10 7 EXT CLK 6 5 DIV-BY-4 DIV-BY-16 3 2 8 ISUPPY (mA) 6 DIV-BY-1 DIV-BY-1 ISUPPY (mA) ISUPPY (mA) DIV-BY-1 7 EXT CLK 8 6 DIV-BY-4 DIV-BY-16 4 0.1 1 10 100 fCUTOFF (kHz) 4 0.1 1 10 100 0.1 1 10 100 fCUTOFF (kHz) fCUTOFF (kHz) 1569-6 G05 4 3 DIV-BY-4 1569-6 G06 1569-6 G07 LTC1569-6 U U U PIN FUNCTIONS IN +/IN – (Pins 1, 2): Signals can be applied to either or both input pins. The DC gain from IN + (Pin 1) to OUT (Pin␣ 8) is 1.0, and the DC gain from Pin 2 to Pin 8 is –1. The input range, input resistance and output range are described in the Applications Information section. Input voltages which exceed the power supply voltages should be avoided. Transients will not cause latchup if the current into/out of the input pins is limited to 20mA. GND (Pin 3): The GND pin is the reference voltage for the filter and should be externally biased to 2V (1.11V) to maximize the dynamic range of the filter in applications using a single 5V (3V) supply. For single supply operation, the GND pin should be bypassed with a quality 1µF ceramic capacitor to V – (Pin 4). The impedance of the circuit biasing the GND pin should be less than 2kΩ as the GND pin generates a small amount of AC and DC current. For dual supply operation, connect Pin␣ 3 to a high quality DC ground. A ground plane should be used. A poor ground will increase DC offset, clock feedthrough, noise and distortion. V –/V + (Pins 4, 7): For 3V, 5V and ±5V applications a quality 1µF ceramic bypass capacitor is required from V + (Pin 7) to V – (Pin 4) to provide the transient energy for the internal clock drivers. The bypass should be as close as possible to the IC. In dual supply applications (Pin 3 is grounded), an additional 0.1µF bypass from V + (Pin 7) to GND (Pin 3) and V – (Pin 4) to GND (Pin 3) is recommended. The maximum voltage difference between GND (Pin 3) and V + (Pin 7) should not exceed 5.5V. DIV/CLK (Pin 5): DIV/CLK serves two functions. When the internal oscillator is enabled, DIV/CLK can be used to engage an internal divider. The internal divider is set to 1:1 when DIV/CLK is shorted to V – (Pin 4). The internal divider is set to 4:1 when DIV/CLK is allowed to float (a 100pF bypass to V – is recommended). The internal divider is set to 16:1 when DIV/CLK is shorted to V + (Pin 7). In the divide-by-4 and divide-by-16 modes the power supply current is reduced by as much as 40%. When the internal oscillator is disabled (RX shorted to V –) DIV/CLK becomes an input pin for applying an external clock signal. For proper filter operation, the clock waveform should be a squarewave with a duty cycle as close as possible to 50% and CMOS voltages levels (see Electrical Characteristics section for voltage levels). DIV/ CLK pin voltages which exceed the power supply voltages should be avoided. Transients will not cause latchup if the fault current into/out of the DIV/CLK pin is limited to 40mA. RX (Pin 6): Connecting an external resistor between the RX pin and V + (Pin 7) enables the internal oscillator. The value of the resistor determines the frequency of oscillation. The maximum recommended resistor value is 40k and the minimum is 3.8k. The internal oscillator is disabled by shorting the RX pin to V – (Pin 4). (Please refer to the Applications Information section.) OUT (Pin 8): Filter Output. This pin can drive 10kΩ and/or 40pF loads. For larger capacitive loads, an external 100Ω series resistor is recommended. The output pin can exceed the power supply voltages by up to ±2V without latchup. 5 LTC1569-6 W BLOCK DIAGRA IN + 1 8 OUT 10TH ORDER LINEAR PHASE FILTER NETWORK IN – 2 7 V+ REXT POWER CONTROL GND 3 6 RX DIVIDER/ BUFFER V– 4 5 DIV/CLK PRECISION OSCILLATOR 1569-6 BD U U W U APPLICATIONS INFORMATION Table1. fCUTOFF vs REXT, VS = 3V, TA = 25°C, Divide-by-1 Mode Self-Clocking Operation The LTC1569-6 features a unique internal oscillator which sets the filter cutoff frequency using a single external resistor. The design is optimized for VS = 3V, fCUTOFF = 64kHz, where the filter cutoff frequency error is typically <1% when a 0.1% external 10k resistor is used. With different resistor values and internal divider settings, the cutoff frequency can be accurately varied from 1kHz to 64kHz. As shown in Figure 1, the divider is controlled by the DIV/CLK (Pin 5). Table 1 summarizes the cutoff frequency vs external resistor values for the divide-by-1 mode. + 1 IN 2 IN – OUT 8 + 7 V REXT LTC1569-6 3 4 fCUTOFF = GND V– RX DIV/CLK 6 DIVIDE-BY-16 5 64kHz (10k/REXT) 100pF DIVIDE-BY-1 1, 4 OR 16 Figure 1 V+ DIVIDE-BY-4 V– 1569-6 F01 REXT Typical fCUTOFF Typical Variation of fCUTOFF 3844Ω* N/A ±3.0% 5010Ω* N/A ±2.5% 10k 64kHz ±1% 20.18k 32kHz ±2.0% 40.2k 16kHz ±3.5% *REXT values less than 10k can be used only in the divide-by-16 mode. In the divide-by-4 and divide-by-16 modes, the cutoff frequencies in Table 1 will be lowered by 4 and 16 respectively. When the LTC1569-6 is in the divide-by-4 and divide-by-16 modes the power is automatically reduced. This results in up to a 40% power savings. The power reduction in the divide-by-4 and divide-by-16 modes, however, effects the fundamental oscillator frequency. Hence, the effective divide ratio will be slightly different from 4:1 or 16:1 depending on VS, TA and REXT. Typically this error is less than 1% (Figures 4 and 6). The cutoff frequency is easily estimated from the equation in Figure 1. Examples 1 and 2 illustrate how to use the graphs in Figures 2 through 7 to get a more precise estimate of the cutoff frequency. Example 1: LTC1569-6, REXT = 20k, VS = 3V, divide-by-16 mode, DIV/CLK (Pin␣ 5) connected to V + (Pin 7), TA = 25°C. 6 LTC1569-6 U U W U APPLICATIONS INFORMATION Using the equation in Figure 1, the approximate filter cutoff frequency is fCUTOFF = 64kHz • (10k/20k) • (1/16) = 2kHz. Using the equation in Figure 1, the approximate filter cutoff frequency is fCUTOFF = 64kHz • (10k/10k) • (1/1) = 64kHz. For a more precise fCUTOFF estimate, use Table 1 to get a value of fCUTOFF when REXT = 20k and use the graph in Figure 6 to find the correct divide ratio when VS = 3V and REXT = 20k. Based on Table 1 and Figure 6, fCUTOFF = 32kHz • (20.18k/20k) • (1/16.02) = 2.01kHz. For a more precise fCUTOFF estimate, use Figure 2 to correct for the supply voltage when VS = 5V. From Table␣ 1 and Figure 2, fCUTOFF = 64k • (10k/10k) • 0.970 = 62.1kHz. From Table 1, the part-to-part variation of fCUTOFF will be ±2%. From the graph in Figure 7, the 0°C to 70°C drift of fCUTOFF will be – 0.2% to 0.2%. Example 2: LTC1569-6, REXT = 10k, VS = 5V, divide-by-1 mode, DIV/CLK (Pin␣ 5) connected to V – (Pin 4), TA = 25°C. The oscillator is sensitive to transients on the positive supply. The IC should be soldered to the PC board and the PCB layout should include a 1µF ceramic capacitor between V + (Pin 7) and V – (Pin 4) , as close as possible to the IC to minimize inductance. Avoid parasitic capacitance on RX and avoid routing noisy signals near RX (Pin 6). Use 1.04 1.010 REXT = 5k REXT = 10k REXT = 20k REXT = 40k 1.02 1.008 NORMALIZED FILTER CUTOFF NORMALIZED FILTER CUTOFF 1.03 1.01 1.00 0.99 0.98 0.97 0.96 1.006 VS = 3V VS = 5V VS = 10V 1.004 1.002 1.000 0.998 0.996 0.994 0.992 2 4 6 8 0.990 –50 10 –25 VSUPPLY (V) 0 25 50 TEMPERATURE (°C) 1569-6 F02 100 1569-6 F03 Figure 3. Filter Cutoff vs Temperature, Divide-by-1 Mode, REXT = 10k Figure 2. Filter Cutoff vs VSUPPLY, Divide-by-1 Mode, TA = 25°C 4.08 1.010 REXT = 5k REXT = 10k REXT = 20k REXT = 40k 1.008 NORMALIZED FILTER CUTOFF DIVIDE RATIO 75 4.04 4.00 1.006 VS = 3V VS = 5V VS = 10V 1.004 1.002 1.000 0.998 0.996 0.994 0.992 3.96 2 4 6 8 10 VSUPPLY (V) 1569-6 F04 Figure 4. Typical Divide Ratio in the Divide-by-4 Mode, TA = 25°C 0.990 –50 –25 0 25 50 TEMPERATURE (°C) 75 100 1569-6 F05 Figure 5. Filter Cutoff vs Temperature, Divide-by-4 Mode, REXT = 10k 7 LTC1569-6 U U W U APPLICATIONS INFORMATION 16.32 1.010 1.008 NORMALIZED FILTER CUTOFF DIVIDE RATIO REXT = 5k REXT = 10k REXT = 20k REXT = 40k 16.16 16.00 1.006 VS = 3V VS = 5V VS = 10V 1.004 1.002 1.000 0.998 0.996 0.994 0.992 15.84 2 4 6 8 10 VSUPPLY (V) 0.990 –50 –25 0 25 50 TEMPERATURE (°C) 1569-6 F06 75 100 1569-6 F07 Figure 6. Typical Divide Ratio in the Divide-by-16 Mode, TA = 25°C Figure 7. Filter Cutoff vs Temperature, Divide-by-16 Mode, REXT = 10k a ground plane connected to V – (Pin 4) for single supply applications. Connect a ground plane to GND (Pin 3) for dual supply applications and connect V – (Pin 4) to a copper trace with low thermal resistance. input signal at IN + should be centered around the DC voltage at IN –. The input can also be AC coupled, as shown in the Typical Applications section. Input and Output Voltage Range The input signal range includes the full power supply range. The output range is typically (V – + 50mV) to (V + – 0.8V) when using a single 3V supply with the GND (Pin 3) voltage set to 1.11V. In other words, the output range is typically 2.1VP-P for a 3V supply. Similarly, the output range is typically 3.9VP-P for a single 5V supply when the GND (Pin 3) voltage is 2V. For ±5V supplies, the output range is typically 8.5VP-P. The LTC1569-6 can be driven with a single-ended or differential signal. When driven differentially, the voltage between IN + and IN – (Pin 1 and Pin 2) is filtered with a DC gain of 1. The single-ended output voltage OUT (Pin 8) is referenced to the voltage of the GND (Pin 3). The common mode voltage of IN + and IN – can be any voltage that keeps the input signals within the power supply range. For noninverting single-ended applications, connect IN – to GND or to a quiet DC reference voltage and apply the input signal to IN +. If the input is DC coupled then the DC gain from IN + to OUT will be 1. This is true given IN + and OUT are referenced to the same voltage, i.e., GND, V – or some other DC reference. To achieve the distortion levels shown in the Typical Performance Characteristics the 8 For inverting single-ended filtering, connect IN+ to GND or to quiet DC reference voltage. Apply the signal to IN –. The DC gain from IN – to OUT is –1, assuming IN – is referenced to IN + and OUT is reference to GND. Refer to the Typical Performance Characteristics section to estimate the THD for a given input level. Dynamic Input Impedance The unique input sampling structure of the LTC1569-6 has a dynamic input impedance which depends on the configuration, i.e., differential or single-ended, and the clock frequency. The equivalent circuit in Figure 8 illustrates the input impedance when the cutoff frequency is 64kHz. For other cutoff frequencies replace the 125k value with 125k • (64kHz/fCUTOFF). When driven with a single-ended signal into IN – with IN + tied to GND, the input impedance is very high (~10MΩ). When driven with a single-ended signal into IN + with IN – tied to GND, the input impedance is a 125k resistor to GND. When driven with a complementary signal whose common mode voltage is GND, the IN+ input appears to have 125k to GND and the IN – input appears to have –125k to GND. To make the effective IN – impedance 125k when driven differentially, place a 62.5k resistor from IN – to GND. For other cutoff frequencies use 62.5k • (64kHz/ LTC1569-6 U W U U APPLICATIONS INFORMATION fCUTOFF), as shown in the Typical Applications section. The typical variation in dynamic input impedance for a given clock frequency is ±10%. Wideband Noise The wideband noise of the filter is the RMS value of the device’s output noise spectral density. The wideband noise data is used to determine the operating signal-tonoise at a given distortion level. The wideband noise is nearly independent of the value of the clock frequency and excludes the clock feedthrough. Most of the wideband noise is concentrated in the filter passband and cannot be removed with post filtering (Table 2). Table 3 lists the typical wideband noise for each supply. Table 2. Wideband Noise vs Supply Voltage, Single 3V Supply Bandwidth Total Integrated Noise DC to fCUTOFF 80µVRMS DC to 2 • fCUTOFF 95µVRMS DC to fCLK 110µVRMS Table 3. Wideband Noise vs Supply Voltage, fCUTOFF = 64kHz Power Supply Total Integrated Noise DC to 2 • fCUTOFF 3V 95µVRMS 5V 100µVRMS ±5V 105µVRMS Clock Feedthrough Clock feedthrough is defined as the RMS value of the clock frequency and its harmonics that are present at the filter’s OUT pin (Pin 8). The clock feedthrough is measured with IN + and IN – (Pins 1 and 2) grounded and depends on the PC board layout and the power supply decoupling. Table␣ 4 shows the clock feedthrough (the RMS sum of the first 11 harmonics) when the LTC1569-6 is self-clocked with REXT = 10k, DIV/CLK (Pin 5) open (divide-by-4 mode). The clock feedthrough can be reduced with a simple RC post filter. DC accuracy is defined as the error in the output voltage after DC offset and DC gain errors are removed. This is similar to the definition of the integral nonlinearity in A/D converters. For example, after measuring values of VOUT(DC) vs VIN(DC) for a typical LTC1569-6, a linear regression shows that VOUT(DC) = VIN(DC) • 0.99854 + 0.00134V is the straight line that best fits the data. The DC accuracy describes how much the actual data deviates from this straight line (i.e., DCERROR = VOUT(DC) – (VIN(DC) • 0.99854 + 0.00134V). In a 12-bit system with a full-scale value of 2V, the LSB is 488µV. Therefore, if the DCERROR of the filter is less than 488µV over a 2V range, the filter has 12-bit DC accuracy. Figure 9 illustrates the typical DC accuracy of the LTC1569-6 on a single 5V supply. DC Offset The output DC offset of the LTC1569-6 is trimmed to less than ±5mV. The trimming is performed with VS = 1.9V, –1.1V with the filter cutoff frequency set to 4kHz (REXT = 10k, DIV/CLK shorted to V +). To obtain optimum DC offset performance, appropriate PC layout techniques should be used. The filter IC should be soldered to the PC board. The power supplies should be well decoupled including a 1µF ceramic capacitor from V + (Pin 7) to V – (Pin 4). A ground plane should be used. Noisy signals should be isolated from the filter input pins. When the power supply is 3V, the output DC offset should change less than ±2mV when the clock frequency varies from 64kHz to 4096kHz. When the clock frequency is fixed, the output DC offset will typically change by less than ±3mV (±15mV) when the power supply varies from 3V to 5V (±5V) in the divide-by-1 mode. In the divide-by4 or divide-by-16 modes, the output DC offset will typically change less than – 9mV (– 27mV) when the power supply varies from 3V to 5V (±5V). The offset is measured with respect to GND (Pin 3). Aliasing Table 4. Clock Feedthrough Power Supply DC Accuracy Feedthrough 3V 0.1mVRMS 5V 0.3mVRMS ±5V 0.9mVRMS Aliasing is an inherent phenomenon of sampled data filters. In lowpass filters significant aliasing only occurs when the frequency of the input signal approaches the sampling frequency or multiples of the sampling fre- 9 LTC1569-6 U U W U APPLICATIONS INFORMATION quency. The LTC1569-6 samples the input signal twice every clock period. Therefore, the sampling frequency is twice the clock frequency and 128 times the filter cutoff frequency. Input signals with frequencies near 2 • fCLK ± fCUTOFF will be aliased to the passband of the filter and appear at the output unattenuated. 488 IN – + 2 244 125k DC ERROR (µV) i= – IN + – GND – 8 OUT + 125k 0 –244 125k IN + 1 VS = 5V REXT = 10k TA = 25°C – –488 –1.5 + GND 3 –1.0 –0.5 1569-6 F06 0 0.5 VIN DC (V) 1.0 1.5 1569-6 F09 Figure 8 Figure 9 U TYPICAL APPLICATIO S Single 3V, AC Coupled Input, 64kHz Cutoff Frequency Single 3V Operation, AC Coupled Input, 64kHz Cutoff Frequency 3V 2 IN + IN – V+ 8 7 3 GND RX 32µs VOUT 28µs REXT = 10k 3V 6 1µF 4 fCUTOFF = V – DIV/CLK 0 1µF LTC1569-6 3.48k 2k OUT 5 ( )( ) 10k 20k 30k 40k 50k 60k 24µs 70k –20 –30 –40 –50 1569-6 TA02 –60 64kHz 10k –70 n=1 REXT –80 n = 1, 4, 16 FOR PIN 5 AT GROUND, OPEN, V + 0 –10 GAIN (dB) 1 –90 0 40k 50k 60k 70k 80k 90k 100k 110k 120k 130k 140k 150k FREQUENCY (Hz) 1569-6 TA02a 10 GROUP DELAY 0.1µF VIN LTC1569-6 U TYPICAL APPLICATIO S Single 3V Supply Operation, DC Coupled, 16kHz Cutoff Frequency VIN 1 IN + 3V 2 IN – V+ 8 7 VOUT REXT = 10k 5V 3V 1µF LTC1569-6 3.48k 3 2k OUT Single 5V Operation, 50kHz Cutoff Frequency, DC Coupled Differential Inputs with Balanced Input Impedance GND RX fCUTOFF = V– DIV/CLK 6 10k n=4 REXT IN + OUT VIN – 2 IN – V+ 8 7 VOUT REXT = 12.8k 5V 1µF LTC1569-6 80.6k 3 LT®1460-2.5 OUT (SOT-23) GND GND RX 6 1µF 5 4 100pF ( )( ) 64kHz 1 IN 1µF 4 VIN + 1569-6 TA04 fCUTOFF ~ n = 1, 4, 16 FOR PIN 5 AT GROUND, OPEN, V + V– DIV/CLK 5 1569-6 TA03 ( )( ) 64kHz 10k n=1 12.8k n = 1, 4, 16 FOR PIN 5 AT GROUND, OPEN, V + ±5V Supply Operation, DC Coupled Filter with External Clock Source VIN 1 IN + OUT 2 IN – V+ 8 VOUT fCUTOFF = fCLK/64 7 5V 0.1µF LTC1569-6 3 –5V 0.1µF 4 GND V– RX DIV/CLK 6 –5V 5 5V 0V fCLK ≤ 5MHz 1569-6 TA05 1µF Pulse Shaping Circuit for Single 3V Operation, 128kbps 2-Level Data, 64kHz Cutoff Filter 2-Level, 128kbps Eye Diagram 3V 20k IN + OUT 8 LTC1569-6 7.32k* 3V 2 20k IN – V+ 7 REXT = 10k 3V 1µF 3.48k 3 2k VOUT GND RX 400mV/DIV 1 128ksps DATA 6 1µF 4 V– DIV/CLK 5 1569-6 TA06 * SEE APPLICATIONS INFORMATION, “INPUT AND OUTPUT VOLTAGE RANGE” 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. 2µs/DIV 1569-6 TA08 11 LTC1569-6 U TYPICAL APPLICATIO S Pulse Shaping Circuit for Single 3V Operation, 200kbps (100ksps) 4-Level Data, 64kHz Cutoff Filter 4-Level, 200kbps (100ksps) Eye Diagram 3V 20k 1 IN + OUT 8 VOUT LTC1569-6 2.49k* 100ksps DATA 3V D0 2 IN – V+ 7 3 20k 2k 3V 1µF 3.48k 9.31k* REXT = 10k GND RX 400mV/DIV D1 6 1µF 4 V– DIV/CLK 5 1569-6 TA06 * SEE APPLICATIONS INFORMATION, “INPUT AND OUTPUT VOLTAGE RANGE” U PACKAGE DESCRIPTION 2µs/DIV 1569-6 TA09 Dimensions in inches (millimeters) unless otherwise noted. S8 Package 8-Lead Plastic Small Outline (Narrow 0.150) (LTC DWG # 05-08-1610) 0.189 – 0.197* (4.801 – 5.004) 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) 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 7 8 6 5 0.004 – 0.010 (0.101 – 0.254) 0.050 (1.270) BSC 0.150 – 0.157** (3.810 – 3.988) 0.228 – 0.244 (5.791 – 6.197) 1 2 3 4 SO8 1298 RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LTC1064-3 Linear Phase, Bessel 8th Order Filter fCLK/fCUTOFF = 75/1 or 150/1, Very Low Noise LTC1064-7 Linear Phase, 8th Order Lowpass Filter fCLK/fCUTOFF = 50/1 or 100/1, fCUTOFF(MAX) = 100kHz LTC1069-7 Linear Phase, 8th Order Lowpass Filter fCLK/fCUTOFF = 25/1, fCUTOFF(MAX) = 200kHz, SO-8 LTC1164-7 Low Power, Linear Phase Lowpass Filter fCLK/fCUTOFF = 50/1 or 100/1, IS = 2.5mA, VS = 5V LTC1264-7 Linear Phase, 8th Order Lowpass Filter fCLK/fCUTOFF = 25/1 or 50/1, fCUTOFF(MAX) = 200kHz LTC1562/LTC1562-2 Universal, 8th Order Active RC Filter fCUTOFF(MAX) = 150kHz (LTC1562) fCUTOFF(MAX) = 300kHz (LTC1562-2) LTC1563-2/LTC1563-3 Active RC, 4th Order Lowpass fCUTOFF(MAX) = 300kHz, Very Low Noise LTC1569-7 Linear Phase DC Accurate, 10th Order fCUTOFF(MAX) = 300kHz, No Clock Required 12 Linear Technology Corporation 15696f LT/TP 0500 4K • PRINTED IN THE USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com LINEAR TECHNOLOGY CORPORATION 1999