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For Video Equipment
MN3113F
Vertical Driver LSI for Video Camera CCD Area Image Sensor
Overview
The MN3113F is a vertical driver LSI for a two-dimensional interline CCD image sensor. It features a built-in power supply circuit that, in conjunction with such external components as six booster capacitors and two voltage stabilization capacitors, produces stabilized +15.0V and -10.0V power supplies from a +5.0V input and HD pulses. The MN3113F makes it possible to drive a CCD image sensor on a single 5 volt power supply.
Pin Assignment
VEE VHH OSUB VL2 VL1 OV1 VM13 OV3 OV2 VM24 OV4
Features
Single 5 volt power supply Adjustable output voltage for regulated voltage circuit
Applications
Video cameras
C1- C2- C3 - C4 - C5 - OVEE C6 - VCC1 C6+ OVDD HD
1 2 3 4 5 6 7 8 9 10 11
ISUB CH1 IV1 IV3 CH2 SENSE2 VOUT- VIN - GND C1+ C3+
34 35 36 37 38 39 40 41 42 43 44
33 32 31 30 29 28 27 26 25 24 23
22 21 20 19 18 17 16 15 14 13 12
VH VDD VCC2 IV2 IV4 SENSE1 VOUT+ VIN+ CAP3 CAP2 CAP1
(TOP VIEW) QFP044-P-1010
SDB00056BEM
1
MN3113F
Block Diagram
For Video Equipment
OSUB
VM13
VM24
OV1
OV3
OV2
OV4 23
VHH
VL1
32
31
29
28
27
26
25
24
VL2 VEE ISUB IV1 CH1 IV3 CH2
30 33 34 36 35 37 38 19 18 Tristate driver Tristate driver
22
VH
21 VDD 20 VCC2
IV2 IV4
SENSE2 VOUT- VIN - GND
39 40 41 42 Negative regulated voltage output Positive regulated voltage output
17 Inverter circuit 16
SENSE1 VOUT+
15 14 13 12 11 Negative and positive boosting voltage generator
VIN+ CAP3 CAP2 CAP1 HD
43
44
1
2
3
4
5
7
OVEE
9
2
OVDD
VCC1
C1+
C3+
C3 -
C4 -
C5 -
C6 -
C6+
C1-
C2-
10
6
8
For Video Equipment
Pin Descriptions
Pin No. 8 20 42 22 32 27 24 29 30 21 33 15 41 11 19 18 36 37 35 38 34 17 39 43 1 2 44 3 4 5 Symbol VCC1 VCC2 GND VH VHH VM13 VM24 VL1 VL2 VDD VEE VIN+ VIN - HD IV2 IV4 IV1 IV3 CH1 CH2 ISUB SENSE1 SENSE2 C1+ C1- C2+ C2- C3+ C3 - C4 - C5 - C4 connection C5 connection O O C3 connection O C2 connection O Pin Name "H" level power supply for input block "L" level power supply for input block "H" level power supply for vertical driver "H" level power supply for SUB driver "M" level power supply for vertical driver "L" level power supply for vertical driver "L" level input for SUB driver Power supply 1 for driver Power supply 2 for driver Positive regulated voltage block voltage input Negative regulated voltage block voltage input HD pulse input Transfer pulse input Transfer pulse input Transfer pulse input Transfer pulse input Charge pulse input Charge pulse input SUB pulse input Positive voltage sensing input Negative voltage sensing input C1 connection O I I I I I I I I I I I I I I I I I I I I I/O I
MN3113F
Function Description "H" level input for 5 volt circuits "L" level input for 5 volt circuits "H" level input for high-voltage circuits "H" level input for high-voltage circuits "M" level input for high-voltage circuits "L" level input for high-voltage circuits "L" level input for high-voltage circuits "H" level for high-voltage circuits "L" level for high-voltage circuits Positive regulated voltage block voltage input pin Negative regulated voltage block voltage input pin HD pulse input pin Charge transfer pulse input pin Charge transfer pulse input pin Charge transfer pulse input pin Charge transfer pulse input pin Charge readout pulse input pin Charge readout pulse input pin Unwanted charge rejection pulse input pin Positive voltage control sensing pin Negative voltage control sensing pin Booster block voltage charging capacitor connection pins Booster block voltage charging capacitor connection pins Booster block voltage charging capacitor connection pins Booster block voltage charging capacitor connection pins Booster block voltage charging capacitor connection pins
3
MN3113F
Pin Descriptions (continued)
Pin No. 7 9 10 6 16 40 23 25 26 28 31 12 13 14 Symbol C6 - C6+ OVDD OVEE VOUT+ VOUT- OV4 OV2 OV3 OV1 OSUB CAP1 CAP2 CAP3 Booster block positive voltage output Booster block negative voltage output Positive regulated voltage output Negative regulated voltage output Binary transfer pulse output Binary transfer pulse output Tristate transfer pulse output Tristate transfer pulse output SUB pulse output Stabilizing capacitor connection O O O O O O O O O O Pin Name C6 connection pins I/O O
For Video Equipment
Function Description Booster block voltage charging capacitor connection pins Booster block positive voltage output pin Booster block negative voltage output pin Positive regulated voltage output pin Negative regulated voltage output pin Binary (VM24 , VL1) transfer pulse output pin Binary (VM24 , VL1) transfer pulse output pin Tristate (VH , VM13 , VL1) transfer pulse output pin Tristate (VH , VM13 , VL1) transfer pulse output pin Unwanted charge (VHH , VL2) rejection pulse input pin Pins for connecting capacitors for internal voltage stabilization circuits
4
For Video Equipment
Functional Description Binary transfer pulses (vertical driver block)
IV2 IV4 H L OV2 OV4 L M
MN3113F
Tristate transfer pulses (vertical driver block)
CH1 CH2 H L
*1 IV1, IV2, IV3, IV4, CH1, CH2 H: VCC L: GND OV1, OV2, OV3, OV4 H: VH M: VM13 , or VM24 L: VL1
IV1 IV3 H L H L
OV1 OV3 L M L H
Unwanted charge rejection pulses (SUB driver block)
ISUB H L
*1 ISUB H: VCC L: GND OSUB H: VHH L: VL2
OSUB L H
5
MN3113F
Electrical Characteristics (1) DC characteristics
VHH=VH=15.0V , VM13=VM24=1.0V , GND=0.0V , VCC1=VCC2=5.0V (=VCC), VL1 =-7.0V , VL2 =-10.0V , Ta=+25C
For Video Equipment
Parameter Quiescent supply current Operating supply current Power supply output pins Positive voltage stabilization circuit output voltage Negative voltage stabilization circuit output voltage Input pins "H" level voltage "L" level voltage Input leak current Output pins 1 (Binary output) Output voltage "M" level Output voltage "L" level Output on resistance "M" level Output on resistance "L" level
Symbol IDDST IDDDYN VOUT+ VOUT-
Test conditions VI=GND , VCC VI=GND , VCC VI=GND , VCC , IO=7mA fINHD=15.7kHz VI=GND , VCC , IO=-2mA fINHD=15.7kHz
min
typ 2 45
max 4 90 15.5 -9.5
Unit mA mA V V
OVDD , OVEE 14.5 -10.5 15.0 -10.0
IV1 , IV2 , IV3 , IV4 , CH1 , CH2 , ISUB , HD VIH VIL ILI VOM1 VOL1 RONM1 RONL1 VOH2 VOM2 VOL2 RONH2 RONM2 RONL2 VOHH3 VOL3 RONHH3 RONL3 VI=0 to 5V OV2 , OV4 VI=GND , VCC , IOM1=-1mA VI=GND , VCC , IOL1=1mA IOM1=-50mA IOL1=50mA VI=GND , VCC , IOH2=-1mA VI=GND , VCC , IOM2=-1mA VI=GND , VCC , IOL2=1mA IOH2=-50mA IOM2=50mA IOL2=50mA VI=GND , VCC , IOHH3 =-1mA VI=GND , VCC , IOL3=1mA IONHH3=-50mA IONL3=50mA 14.9 VL2 14.9 0.9 VL1 0.9 VL1 VM24 -6.9 40 40 VH VM13 -6.9 50 40 40 VHH -9.9 50 40 V V V V V V V 3.5 GND VCC 1.5 1 V V A
Output pins 2 (Tristate output) Output voltage "H" level Output voltage "M" level Output voltage "L" level Output on resistance "H" level Output on resistance "M" level Output on resistance "L" level Output pin 3 (SUB output) Output voltage "H" level Output voltage "L" level Output on resistance "H" level Output on resistance "L" level
OV1 , OV3
OSUB
6
For Video Equipment
(2) AC characteristics
VHH=VH=15.0V , VM13=VM24=1.0V , GND=0.0V , VCC1=VCC2=5.0V (=VCC) , VL1=-7.0V , VL2=-10.0V , Ta=+25C
MN3113F
Parameter Symbol Test Conditions Output pins 1 (Binary output) OV2 , OV4 Transmission delay time Rise time Fall time Output pins 2 (Tristate output) Transmission delay time Transmission delay time Rise time Fall time Rise time Fall time Output pin 3 (SUB output) Transmission delay time Risie time Fall time tPLM tPML tTLM tTML OV1 , OV3 tPLM tPML tPMH tPHM tTLM tTML tTMH tTHM OSUB tPLHH tPHHL tTLHH tTHHL No load From "L" level to "H" level No load From "L" level to "M" level No load From "M" level to "H" level No load From "L" level to "M" level
min
typ 100 200
max 200 300
Unit ns ns
100 200 200 200
200 400 300 300
ns ns ns ns
100 200
200 300
ns ns
7
MN3113F
Timing Chart 1. Binary transfer pulses
63.5s 2s IV2 254s
For Video Equipment
63.5s H L M L
OV2
2. Binary transfer pulses
IV4 H L M L
OV4
3. Tristate transfer pulses
IV1 3s CH1 H L H L H OV1 M L
4. Tristate transfer pulses
IV3 CH2 H L H L H M L
OV3
5. SUB pulses
ISUB H L H OSUB L
8
For Video Equipment
Application Circuit Example
Diode with VF =0.7V
to CCD's source follower power D7 supply for OD, RD, and IS pins
MN3113F
Schottky barrier diode
< -7.9V > to CCD's
PT pin
to CCD's oV pin
R4
D6 C18
*1
D3
D4
D5
*1
+
C17
+
< -10.0V >
C19
+
< -7.2V >
< +15.0V >
C20
R2
R5
+
30 29 28 27 26 25 24 23
33
32
VEE
OSUB
31
+
VL2
VHH
VL1
OV1
OV3
OV2
VM13
VM24
OV4
from clock generator
34 35 36 37 38
C10
ISUB CH1 IV1 IV3 CH2 SENSE2 VOUT- VIN - GND C1+ C3+
VH VDD VCC2 IV2
22 21 20 19 18 17 16 15 14 13 12
C12
IV4 SENSE1
42 43 44
C3
CAP2 CAP1
+
10 OVDD OVEE C3 - C4 - C5 - VCC1 C6 - C1- C2- C6+ 11 HD
C1
1
2
3
4
5
6
7
8
9
D1
C6
+ +
C7
C5
+
C8 C2 C4
D2
*2
*2
+
+
+
Notes *1: These diodes must have a VF of 0.7V. *2: These diodes must be Schottky barrier diodes (MA723). *3: The booster circuit's electrolytic capacitors (C1 to C8) and voltage stabilization capacitors (C9 and C10) must have little impedance fluctuation at low temperatures.
5 volt input
C1
+
C13
41
VIN+ CAP3
C9
+
39 40
MN3113F
VOUT+
+
from clock generator
R1
C14
C15
R3
C16
9
MN3113F
Package Dimensions (Unit: mm)
QFP044-P-1010
For Video Equipment
12.30.4 10.00.2 33 23 22 (1.0) 10.00.2 44 12 1 (1.0)
0.8
34
11 0.350.1 2.00.2 2.10.3 1.150.2
0.10.1
0.15 -0.05
+0.1
12.30.4
0 to 10 0.60.2
0.1 Seating plane
Note) The package of this product will be changed to lead-free type (QFP044-P-1010E). See the new package dimensions section later of this datasheet.
10
For Video Equipment
Usage Notes External components
1. This product requires two Schottky barrier diodes. We recommend the following components. Schottky barrier diodes: MA723 or equivalents
MN3113F
Ta=25C
Component Schottky barrier diodes
Model number MA723
Typical characteristics IF =200mA, VF 0.55V
Notes
The MN3113F will not operate properly if the components do not satisfy the above specifications.
Normal operation
GND VL1/VL2 OVEE OFF GND
Faulty operation
0.7V or higher VL1/VL2 OVEE Reversal OFF
2. Always use the specified components for peripheral circuits so as to ensure that OVEE and VL do not reverse potentials when the power is turned off. As the above sketch illustrates, allowing OVEE to exceed VL1 and VL2 by more than 0.7 V produces the risk of applying a forward bias to the PN junction, turning on the parasitic transistor, and generating an overcurrent that produces latch-up. If this phenomenon arises, increase the size of capacitor C8 or decrease the size of capacitor C10 to increase the OVEE time constant. (See the sample application circuit for the locations of C8 and C10.)
11
MN3113F
3. Adjusting boost voltages with SENSE pins
For Video Equipment
The MN3113F provides the SENSE pins, SENSE1 and SENSE2, for adjusting the boost voltages (VOUT+ and VOUT- ) with the following procedures. Adjusting the positive boosted voltage (1) Making VOUT+ < 15V Insert a resistor, R, between the SENSE1 pin (pin 17) and the VOUT+ pin (pin 16). The theoretical output voltage at the VOUT+ pin is then given by the following formula. VOUT+' = VCC x 50k + 100k//R 50k (where 100 k//R is the effective resistance of the 100 k resistor and R connected in parallel.) For example, if R is 50 k, VOUT+' = 5 x (2) Making VOUT+ > 15V Insert a resistor, R, between the SENSE1 pin (pin 17) and the GND pin (pin 42). VOUT+' = VCC x 50k//R + 100k 50k//R 50k + 33.3k 50k = 8.3V
Adjusting the negative boosted voltage (1) Making VOUT- < -10V Insert a resistor, R, between the SENSE2 pin (pin 39) and the GND pin (pin 42). VOUT-' = VCC x (2) Making VOUT- > -10V Insert a resistor, R, between the SENSE2 pin (pin 39) and the VOUT- pin (pin 40). VOUT-' = -VCC x 50k + 50k//R 50k 50k + 25k 50k 50k//R + 50k 50k//R
For example, if R is 50 k, VOUT-' = -5 x = -7.5V
Note, however, that the above formulas are mere guidelines, that the internal resistances vary between samples, and that therefore each sample will have to be adjusted. Note also that booster circuit capacity and output load current impose limits on adjustments for boosting VOUT+ above 15V and VOUT- below -10V. (The maximum possible adjustments are 20V for VOUT+ and -15V for VOUT- .)
12
For Video Equipment
New Package Dimensions (Unit: mm)
* QFP044-P-1010E (Lead-free package)
MN3113F
12.300.40 10.000.20 33 34 23
22
(1.00) 44 1 (1.00) 0.80 12 11 0.350.10
10.000.20 12.300.40
2.000.20 2.100.30
1.150.20
0.15-0.05
+0.10
0.100.10
0 to 10 0.600.20
0.10
Seating plane
13
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(1) An export permit needs to be obtained from the competent authorities of the Japanese Government if any of the products or technologies described in this material and controlled under the "Foreign Exchange and Foreign Trade Law" is to be exported or taken out of Japan. (2) The technical information described in this material is limited to showing representative characteristics and applied circuit examples of the products. It does not constitute the warranting of industrial property, the granting of relative rights, or the granting of any license. (3) The products described in this material are intended to be used for standard applications or general electronic equipment (such as office equipment, communications equipment, measuring instruments and household appliances). Consult our sales staff in advance for information on the following applications: * Special applications (such as for airplanes, aerospace, automobiles, traffic control equipment, combustion equipment, life support systems and safety devices) in which exceptional quality and reliability are required, or if the failure or malfunction of the products may directly jeopardize life or harm the human body. * Any applications other than the standard applications intended. (4) The products and product specifications described in this material are subject to change without notice for reasons of modification and/or improvement. At the final stage of your design, purchasing, or use of the products, therefore, ask for the most up-to-date Product Standards in advance to make sure that the latest specifications satisfy your requirements. (5) When designing your equipment, comply with the guaranteed values, in particular those of maximum rating, the range of operating power supply voltage and heat radiation characteristics. Otherwise, we will not be liable for any defect which may arise later in your equipment. Even when the products are used within the guaranteed values, redundant design is recommended, so that such equipment may not violate relevant laws or regulations because of the function of our products. (6) When using products for which dry packing is required, observe the conditions (including shelf life and after-unpacking standby time) agreed upon when specification sheets are individually exchanged. (7) No part of this material may be reprinted or reproduced by any means without written permission from our company.
Please read the following notes before using the datasheets
A. These materials are intended as a reference to assist customers with the selection of Panasonic semiconductor products best suited to their applications. Due to modification or other reasons, any information contained in this material, such as available product types, technical data, and so on, is subject to change without notice. Customers are advised to contact our semiconductor sales office and obtain the latest information before starting precise technical research and/or purchasing activities. B. Panasonic is endeavoring to continually improve the quality and reliability of these materials but there is always the possibility that further rectifications will be required in the future. Therefore, Panasonic will not assume any liability for any damages arising from any errors etc. that may appear in this material. C. These materials are solely intended for a customer's individual use. Therefore, without the prior written approval of Panasonic, any other use such as reproducing, selling, or distributing this material to a third party, via the Internet or in any other way, is prohibited.
2001 MAR

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