CXL1517N/1518N
CMOS-CCD Signal Processor
Description The CXL1517N/1518N are CMOS-CCD signal processors developed for CCD camera complementary color filter array processing system. CXL1517N 452.5-bit × 2, 453.5-bit 1H CCD delay line CXL1518N 300.5-bit × 2, 301.5-bit 1H CCD delay line Features • Single 5V power supply • Low power consumption (Typ.) CXL1517N 120mW CXL1518N 75mW • Built-in peripheral circuits • Built-in CDS (Correlated Double Sampling) circuit Functions • Clock driver • Autobias circuit (Center and black) • Pedestal clamp circuit • CDS circuit • Overflow prevention circuit Absolute Maximum Ratings (Ta = 25°C) • Supply voltage VDD 6 • Operating temperature Topr –10 to +65 • Storage temperature Tstg –55 to +150 • Allowable power dissipation PD 350 Recommended Operating Voltage Range (Ta = 25°C) Supply voltage VDD 4.6 to 5.25 24 pin SSOP (Plastic)
Structure CMOS-CCD
V °C °C mW (SSOP package)
V
Item Clock voltage Low Clock voltage High Clock frequency CXL1517N CXL1518N
Symbol VL VH fCL fCL
Min. VSS 0.7 × VDD
Typ.
Max. 0.3 × VDD VDD
Unit V V MHz MHz
Remarks
7.16 4.77
NTSC: 455fH CCIR: 454fH NTSC: 910fH/3 CCIR: 908fH/3
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–
E91778A78-PS
CXL1517N/1518N
Block Diagram and Pin Configuration (Top View)
XDL1 XDL2
VDD
VDD
VDD
VSS
19
18
5
VSS
8
20
1
VSS
16
2
17
TIMING GENERATOR ABBL 4 A.B. BLACK A.B. CENTER DRIVER PRECHARGE DRAIN PG. GEN. IN-A 23 CLP (n bit) DL A PG. GEN. IN-B 3 CLP (n bit) DL B PG. GEN. IN-C 6 CLP (n + 1 bit) DL C CDS OUTPUT CIRCUIT 9 OUT-C CDS OUTPUT CIRCUIT 11 OUT-B CDS OUTPUT CIRCUIT 14 OUT-A
ABCN 21
CLP PULSE GEN.
OVERFLOW PREVENTION CIRCUIT 22
POTENTIAL CONTROL
CDS
7
10
15
ABOVF
VSS 1 VSS 2 IN-B 3 ABBL 4 VDD 5 IN-C 6 CLP 7 VDD 8 OUT-C 9 VGG 10 OUT-B 11 NC 12
24 NC 23 IN-A 22 ABOVF 21 ABCN 20 VDD 19 XDL1 18 XDL2 17 VSS 16 VSS 15 CDS 14 OUT-A 13 NC
–2–
CDS
CLP
VGG
VSS
CXL1517N/1518N
Pin Description Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Symbol VSS VSS IN-B ABBL VDD IN-C CLP VDD OUT-C VGG OUT-B NC NC OUT-A CDS VSS VSS XDL2 XDL1 VDD ABCN ABOVF IN-A NC I/O — — I O — I I — O O O — — O O — — I I — O O I — GND Signal input B channel (Y) Autobias DC output for Y signal Power supply Signal input C channel (Y) Clamp pulse input Power supply Signal output C channel Output circuit bias DC output Signal output B channel — — Signal output A channel DC output for CDS GND GND Clock pulse input 2 Clock pulse input 1 Power supply Autobias DC output for C signal Autobias DC output for overflow prevention circuit Signal input A channel (C) — Center level bias at no clamp > 100k Output circuit Timing > 100k > 100k Timing Black level bias Analog Black level bias at no clamp > 100k > 100k Output circuit Analog Description Comment
–3–
Electrical Characteristics Ta = 25°C, VDD = 5.0V, VSS = 0V SW conditions Ratings Conditions Min. Typ. Max. 4.2 3.9 2.6 1.2 0.3 V1 — — V6
20 log
fCL = 7.16MHz (CXL1517N) fCL = 4.77MHz (CXL1518N)
Bias conditions E1 4.6 4.3 3.0 2.3 0.8 24 15 –4.5 –3.5
Item SW4 SW1 SW2 SW3 to 6 a a a a a b a a a a a a a a a b a a b a a b a a
Test Symbol point V1 V2 V3 V4 V5 A1 4.8 4.5 3.3 3.5 3.0 35 25 — — — 0 5 12
Unit
Autobias center level
ABCN
V V V V V mA
Autobias black level
ABBL
Overflow prevention circuit Autobias level
ABOVF
CDS source level
CDS
Output circuit bias level
VGG
Current ∗ supply b b a A → V1 B, C → V2 + 0.25V ↓
20 log
CXL1517N
IDD
CXL1518N
Output amplitude (mVp-p) Input amplitude (SIN 100kHz, 100mVp-p)
–4– V6 b a b ↑ ↓ c b b a Note 1) V6 a to c a to c a to c Note 2) Note 3) V6 b b a to c a ↑ ↓ b A → V1 B, C → V2 + 0.25V Note 4)
Insertion gain
IG
dB
Frequency ∗ response
CXL1517N
fG
CXL1518N
Output amplitude (SIN 1MHz, 100mVp-p) –1.5 –0.4 Output amplitude (SIN 100kHz, 100mVp-p) –1.8 –0.8
dB
Linearity
Lin.
%
The insertion gain difference ∆G between channels
0 0
5 1
12 5
% %
Linearity difference between channels
Bch ∆LBC → Cch
Cross-talk between channels CRT
0
1
3
%
CXL1517N/1518N
∗ Standard values are different between CXL1517N and CXL1518N.
CXL1517N/1518N
Notes) 1) Linearity testing For A channel, set input bias to ABCN – 0.2V first, and then set it to ABCN and ABCN + 0.2V. Then input a sine wave of 100kHz and 100mVp-p, and compare the three output amplitudes. For B channel and C channel, set input bias to ABBL + 0.45V first, and then set it to ABBL + 0.25V and ABBL + 0.05V. Then input a sine wave of 100kHz and 100mVp-p, and compare the three output amplitudes. The maximum output amplitude for the respective A, B and C channels is taken as Sout max and the minimum output amplitude as Sout min. The linearity of the respective channels is defined as: Lin. = Sout max – Sout min × 200 [%] Sout max + Sout min 2) Calculation of insertion gain difference As the maximum insertion gain among A, B and C channels is taken as Gmax and the minimum as Gmin, the insertion gain difference between channels ∆G as: ∆G = | 1 – 10 – ( Gmax20 Gmin ) | × 100 [%]
3) Calculation of linearity difference Define B channel linearity as LB and C channel linearily as LC we obtain the difference ∆LBC as: ∆LBC = | LB – LC | [%] 4) Cross-talk calculation CRTa : The cross-talk value of A channel when B and C channels are input : The output value of A channel when A channel is input OUTA-a SW3-a, SW4-a, SW5, 6-b OUTA-bc : The output value of A channel when B and C channels are input (Cross-talk component) SW3-a, SW4-b, SW5, 6-a CRTa = OUTA-bc OUTA-a × 100 [%]
Clock Waveform Timing
(140) ∗ 210ns (52.5) ∗ 87.5ns 10ns 10ns
90% XDL1 50% 10%
90% 50% 10%
17.5ns 10ns
(52.5) ∗ 87.5ns 10ns
90% XDL2 50% 10%
90% 50% 10%
–5–
∗ The value in brackets is for CXL1517N.
CXL1517N/1518N
Electrical Characteristics Test Circuit
a SW1 a b a a V3 V1 XDL XDL 1 2 V4 1µ 16V VDD 3.3k c No signal (GND) b 100kHz, 100mVp-p sine wave 1MHz, 100mVp-p sine wave
b b SW6 SW5 SW4
1µ 1µ 16V 16V
(NC) 24 23 22 21 20 19 18 17 16 15 14
(NC) 13 a b VDD c 3.3k SW3 ×1 L.P.F
1
2
3
4
5
6
7
8
9
10
11 1µ 16V
12 (NC)
1µ 16V
V5
×1 VDD 3.3k
V6
10k 10k 10k E1
V2
A1 VDD a
SW2 b
Application Circuit
XDL XDL VDD 1 2 4.7µ 16V
Input A 0.1µ 16V (NC) 24
VDD 1µ 16V (NC) 3.3k Output A
1µ 1µ 16V 16V 23 22
100p 20 19 18 17 16 15 14
21
13
VDD 1 2 3 1µ 16V 0.1µ 16V Input B 4 5 6 7 8 9 10 11 1µ 16V VDD 3.3k Output C 12 (NC) 3.3k Output B
100p
100p
0.1µ 4.7µ 16V 4.7µ 16V 16V VDD Input CLP VDD C input
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.
–6–
CXL1517N/1518N
Package Outline
Unit: mm
24PIN SSOP(PLASTIC)
+ 0.2 1.25 – 0.1 ∗7.8 ± 0.1 0.1 13
24
A
1 + 0.1 0.22 – 0.05
12 + 0.05 0.15 – 0.02 0.65 0.1 ± 0.1
0.13 M
∗5.6 ± 0.1
0° to 10° NOTE: Dimensions “∗” does not include mold protrusion. DETAIL A
PACKAGE STRUCTURE
PACKAGE MATERIAL SONY CODE EIAJ CODE JEDEC CODE SSOP-24P-L01 SSOP024-P-0056 LEAD TREATMENT LEAD MATERIAL PACKAGE MASS EPOXY RESIN SOLDER/PALLADIUM PLATING 42/COPPER ALLOY 0.1g
–7–
0.5 ± 0.2
7.6 ± 0.2
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