CXL5507M/P CMOS-CCD 1H Delay Line for NTSC Description The CXL5507M/P are CMOS-CCD delay line ICs that provide 1H delay time for NTSC signals including the external low-pass filter. CXL5507M 8 pin SOP (Plastic) CXL5507P 8 pin DIP (Plastic) Features • Single 5V power supply • Low power consumption 50mW (Typ.) • Built-in peripheral circuits Functions • 453-bit CCD register • Clock driver • Auto-bias circuit • Input clamp circuit • Sample-and-hold circuit Absolute Maximum Ratings (Ta = 25°C) 6 V • Supply voltage VDD • Operating temperature Topr –10 to +60 °C • Storage temperature Tstg –55 to +150 °C • Allowable power dissipation PD CXL5507M 350 mW CXL5507P 480 mW Structure CMOS-CCD Recommended Operating Condition (Ta = 25°C) Supply voltage VDD 5 ± 5% V Recommended Clock Conditions (Ta = 25°C) • Input clock amplitude VCLK 0.3 to 1.0 Vp-p (0.5Vp-p typ.) • Clock frequency fCLK 7.159090 MHz • Input clock waveform Sine wave Input Signal Amplitude VSIG 500mVp-p (Typ.), 527mVp-p (Max.) (at internal clamp condition) AB VDD VGA CLK Blook Diagram and Pin Configuration (Top View) 8 7 6 5 Auto-bias circuit Timing circuit Bias circuit Clock driver CCD (453bit) Bias circuit (A) Output circuit Bias circuit (B) (S/H 1bit) VGB 3 4 VSS 2 OUT 1 IN Clamp circuit Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits. –1– E90908A7X-PS CXL5507M/P Pin Description Pin No. Symbol Description I/O Impedance > 10kΩ at no clamp 1 IN I Signal input 2 VGB I Gate control B 3 OUT O Signal output 4 VSS — GND 5 CLK I Clock input 6 VGA O Gate control A 7 VDD — Power supply (5V) 8 AB O Auto-bias DC output 40 to 500Ω > 100kΩ 600 to 200kΩ Description of I/O Signals Input signals are low level clamped and output signals are inverted in relation to the input signals. Also, the clamp condition of input signals are controlled by VGB (Pin 2) conditions. 0V ........ Internal clamp condition 5V ........ Non internal clamp condition Center biased to approx. 2.1V by means of the IC internal resistance (approx. 10kΩ). In this mode, the input signal is limited to APL 50% and the maximum input signal amplitude is 200mVp-p. Input waveform Output waveform Clamp level Electrical Characteristics (Ta = 25°C, VDD = 5V, fCLK = 7.159090MHz, VCLK = 500mVp-p, sine wave) See "Electrical Characteristics Test Circuit" Item Symbol Test condition SW condition Bias condition V1 (V) Min. Typ. Max. Unit Note — 5 10 15 mA 1 –2 0 2 dB 2 0 dB 3 1 2 3 4 5 a a b a Supply current IDD Low frequency gain GL 200kHz, a 500mVp-p, sine wave a b a b Frequency response fg 200kHz ← → 2MHz, b 150mVp-p, sine wave c a a b b 2.1 –2 –1 S/H pulse coupling CP No signal input — b a b a 2.1 — — S/N ratio SN No signal input — b a b c 54 56 — b a b a a 37 40 43 b a b a a 18 20 22 b a b a a 56 60 64 LIS Linearity LIL LIC — 5-staircase wave (For luminance signals only) –2– — 350 mVp-p 4 dB 5 % 6 CXL5507M/P Notes (1) This is the IC supply current value during clock and signal input. (2) GL is the output gain of OUT pin when a 500mVp-p, 200kHz sine wave is fed to IN pin. GL = 20 log OUT pin output voltage [mVp-p] [dB] 500 [mVp-p] (3) Indicates the dissipation at 2MHz in relation to 200kHz. From the output voltage at OUT pin when a 150mVp-p, 200kHz sine wave is fed to IN pin, and from the output voltage at OUT pin when a 150mVp-p, 2MHz sine wave is fed to same, calculation is made according to the following formula. Input bias is tested at 2.1V. fg = 20 log OUT pin otuput voltage (2MHz) [mVp-p] [dB] OUT pin output voltage (200kHz) [mVp-p] (4) The internal clock component to the output signal during no-signal input and the leakage of that high harmonic component are tested. Input bias is tested at 2.1V. Test value (mVp-p) (5) Input no signal noise components are tested with the video noise meter at BPF 10kHz to 3MHz. This is calculated from the output gain (GL), at the input of 200kHz, 500mVp-p and according to the following formula. S/N = –20 • Iog Noise (mVrms) [dB] 0.5 • 10 GL/20 (6) Respective outputs are tested at the input of the 5-staircase waves seen in the figure below (Iuminance signals only) and calculated according to the formula below. (However, output signals become inverted with regards to input.) Va LIS = Vs × 100 [%] Va 100 IRE Vc 500mV Vp Vs 40 IRE –3– LIL = Vp × 100 [%] Va LIC = Vc × 100 [%] Va CXL5507M/P Clock 2fsc (7.159090MHz) sine wave (0.5Vp-p typ.) –4– –5– 5-staircase wave (Luminance signals only) d c SW1 b 200kHz 150mVp-p sine wave 2MHz 150mVp-p sine wave a 200kHz 500mVp-p sine wave Electrical Characteristics Test Circuit b a SW2 V1 1k a SW3 1µ 1M b 2 1 1000p VGB VDD 7 IN AB 8 1µ 3.3µ 5V a 6 1000p 3 b SW4 OUT VGA 1000p 4 VSS CLK 5 0.1µ 9V 2.1k b a BPF Note) ×3 –50 0 –3 10k 3M 7.2M Frequency [Hz] Note) [dB] BPF frequency response SW5 c CLK 2fSC (7.159090MHz) 0.5Vp-p sine wave Noise meter Spectrum analyzer Oscilloscope CXL5507M/P Input Application Circuit 1µ 5V 1M 1 8 1µ 3.3µ –6– 3 6 10 1000p 2.2k PNP: 2SA1175 4 5 0.1µ Delay time 140ns LPF 2.2k 5V NPN: 2SC403 2.2k 2.2k Output Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. 2 12 7 1000p 2fSC 0.5Vp-p sine wave CXL5507M/P CXL5507M/P Example of Representative Characteristics Low frequency gain vs. Supply voltage 1.5 15 1 Low frequency gain [dB] Supply current [mA] Supply current vs. Supply voltage 20 10 5 0 4.75 5 Supply voltage [V] 0.5 0 –0.5 4.75 5.25 Frequency response vs. Supply voltage 5 Supply voltage [V] 5.25 Linearity (LIS) vs. Supply voltage 0 –0.5 Linearity (LIS) [%] Frequency response [dB] 44 –1 36 –1.5 –2 4.75 40 5 Supply voltage [V] 32 4.75 5.25 Linearity (LIL) vs. Supply voltage 5 Supply voltage [V] 5.25 Linearity (LIC) vs. Supply voltage 30 70 66 Linearity (LIC) [%] Linearity (LIL) [%] 25 20 62 58 15 54 10 4.75 5 Supply voltage [V] 50 4.75 5.25 –7– 5 Supply voltage [V] 5.25 CXL5507M/P Low frequency gain vs. Ambient temperature 1.5 15 1 Low frequency gain [dB] Supply current [mA] Supply current vs. Ambient temperature 20 10 5 0 –20 –10 0 10 20 30 40 50 Ambient temperature [°C] 60 0.5 0 –0.5 –20 –10 70 Frequency response vs. Ambient temperature 0 10 20 30 40 50 Ambient temperature [°C] 60 70 Linearity (LIS) vs. Ambient temperature 0 –0.5 Linearity (LIS) [%] Frequency response [dB] 44 –1 40 36 –1.5 –2 –20 –10 0 10 20 30 40 50 Ambient temperature [°C] 60 32 –20 –10 70 Linearity (LIL) vs. Ambient temperature 0 10 20 30 40 50 Ambient temperature [°C] 60 70 Linearity (LIC) vs. Ambient temperature 30 70 66 Linearity (LIC) [%] Linearity (LIL) [%] 25 20 62 58 15 54 10 –20 –10 0 10 20 30 40 50 Ambient temperature [°C] 60 50 –20 –10 70 –8– 0 10 20 30 40 50 Ambient temperature [°C] 60 70 CXL5507M/P Package Outline Unit: mm CXL5507M 8PIN SOP (PLASTIC) + 0.4 1.85 – 0.15 + 0.4 6.1 – 0.1 8 5 1 + 0.2 0.1 – 0.05 6.9 7.9 ± 0.4 + 0.3 5.3 – 0.1 0.15 0.5 ± 0.2 4 + 0.1 0.2 – 0.05 0.45 ± 0.1 1.27 0.24 M PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE SOP-8P-L01 LEAD TREATMENT SOLDER PLATING EIAJ CODE SOP008-P-0300 LEAD MATERIAL 42/COPPER ALLOY PACKAGE MASS 0.1g JEDEC CODE CXL5507P + 0.3 6.4 – 0.1 + 0.4 9.4 – 0.1 5 7.62 8 + 0.1 0.05 0.25 – 8PIN DIP (PLASTIC) 0° to 15° 4 1 + 0.4 3.7 – 0.1 3.0 MIN 0.5 MIN 2.54 0.5 ± 0.1 1.2 ± 0.15 PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE DIP-8P-01 LEAD TREATMENT SOLDER PLATING EIAJ CODE DIP008-P-0300 LEAD MATERIAL COPPER ALLOY PACKAGE MASS 0.5g JEDEC CODE –9–