KODENSHI KKA8356

TECHNICAL DATA
DC-coupled vertical deflection circuit
The KKA8356 is a power circuit for use in 90o and 110ocolour deflection systems for field frequencies
of 50 to 120 Hz. The circuit provides a DC driven vertical deflection output circuit, operating as a
highly efficient class G system.
FEATURES
• Few external components
• Highly efficient fully DC-coupled vertical output bridge circuit
• Vertical flyback switch
• Guard circuit
• Protection against:
– short-circuit of the output pins (7 and 4)
– short-circuit of the output pins to VP
• Temperature (thermal) protection
• High EMC immunity because of common mode inputs
A guard signal in zoom mode
PINNING
SYMBOL
Idrive(pos)
Idrive(neg)
VP
VO(B)
GND
VFB
VO(A)
VO(guard)
VI(fb)
PIN
1
2
3
4
5
6
7
8
9
DESCRIPTION
input power-stage (positive); includes II(sb) signal bias
input power-stage (negative);includes II(sb) signal bias
operating supply voltage
output voltage B
ground
input flyback supply voltage
output voltage A
guard output voltage
input feedback voltage
BLOCK DIAGRAM
1
KKA8356
QUICK REFERENCE DATA
3
SYMBOL
PARAMETER
DC supply
VP
supply voltage
Iq
quiescent supply current
Vertical circuit
I
O(p-p)
output current
(peak-to-peak value)
I
diff(p-p)
differential input current (peak-to-peak value)
V
diff(p-p)
differential input voltage (peak-to-peak value)
Flyback switch
IM
peak output current
VFB
flyback supply voltage
Thermal data
Tstg
storage temperature
Tamb
operating ambient temperature
Tvj
virtual junction temperature
MIN.
TYP.
MAX.
UNIT
9

4.5
30
25

V
mA


2
A
600
1.5

1.8
µA
V




+1
50
A
V
55
25


+150
+75
150
o




C
C
o
C
o
FUNCTIONAL DESCRIPTION
The vertical driver circuit is a bridge configuration. The deflection coil is connected between the output
amplifiers, which are driven in phase opposition. An external resistor (RM) connected in series with the
deflection coil provides internal feedback information. The differential input circuit is voltage driven. An
external resistor (RCON) connected between the differential input determines the output current
through the deflection coil. The relationship between the differential input current and
the output current is defined by: Idiff xRCON = Icoil xRM.The output current is adjustable from 0.5 A (p-p)
to 2
A (p-p) by varying RM. The maximum input differential voltage is 1.8 V. In the application it is
recommended that Vdiff = 1.5 V (typ). This is recommended because of the spread of input current and
the spread in the value of RCON. The flyback voltage is determined by an additional supply voltage VFB.
The principle of operating with two supply voltages (class G) makes it possible to fix the supply
voltage VP optimum for the scan voltage and the second supply voltage VFB optimum for the flyback
voltage. Using this method, very high efficiency is achieved.
The supply voltage VFB is almost totally available as flyback voltage across the coil, this being
possible due to the absence of a decoupling capacitor (not necessary, due to the bridge configuration).
The output circuit is fully protected against the following:
• thermal protection
• short-circuit protection of the output pins (pins 4 and 7)
• short-circuit of the output pins to VP.
A guard circuit VO(guard) is provided. The guard circuit is activated at the following conditions:
• during flyback
• during short-circuit of the coil and during short-circuit of the output pins (pins 4 and 7) to VP or
ground
• during open loop
• when the thermal protection is activated.
This signal can be used for blanking the picture tube screen.
2
KKA8356
LIMITING VALUES
SYMBOL
DC supply
VP
PARAMETER
CONDITIONS
supply voltage
non-operating
MIN.
MAX.


40
25
50
V
V
V

2
A

52
V

+1.5
A
55
25
+150
+75
150
4
40
1

VFB
flyback supply voltage
Vertical circuit
IO(p-p)
output current (peak-to-peak
value)
VO(A)
output voltage (pin 7)
Flyback switch
IM
peak output current
Thermal data
Tstg
storage temperature
Tamb
operating ambient temperature
Tvj
virtual junction temperature
Rth vj-c
resistance vj-case
Rth vj-a
resistance vj-ambient in free air
tsc
short-circuiting time
UNIT
note 1
note 2
o
C
C
o
C
K/W
K/W
hr
o
Notes
1. IO maximum determined by current protection.
2. Up to VP = 18 V.
CHARACTERISTICS
VP = 14.5 V; Tamb = 25 C; VFB = 45 V; fi = 50 Hz; II(sb) = 400 A; unless otherwise specified.
SYMBOL
PARAMETER
DC supply
VP
operating supply voltage
VFB
flyback supply voltage
IP
supply current
Vertical circuit
VO
output voltage swing (scan)
LE
VO
VDF
|Ios|
|Vos|
∆VosT
VO(A)
Gvo
CONDITIONS
no signal; no load
Idiff = 0.6 mA (p-p);
Vdiff = 1.8 V (p-p);
IO = 2 A (p-p)
linearity error
IO = 2 A (p-p);
IO = 50 mA (p-p);
Idiff = 0.3 mA;
output voltage swing (flyback)
V
O(A) - VO(B)
IO = 1 A (M)
forward voltage of the internal
IO = 1 A (M);
efficiency diode (VO(A) - VFB)
Idiff = 0.3 mA
output offset current
Idiff = 0;
II(sb) = 50 to 500 µA
offset voltage at the input of the Idiff = 0;
feedback amplifier (VI(fb) - VO(B))
II(sb) = 50 to 500 µA
output offset voltage as a function Idiff = 0
of temperature
DC output voltage
Idiff = 0;
open-loop voltage gain (V7-4/V1-2)
MIN.
TYP.
MAX.
UNIT
9.0
VP

4.5

30
25
50
55
V
V
mA
13.2


V

1
1
40
4
4

%
%
V

1.5
V





40
mA


24
mV


72
µV/K
6.5
80

V
dB



3
KKA8356
VR
fres
GI
∆GcT
II(sb)
IFB
PSRR
VI(DC)
VI(CM)
Ibias
IO(CM)
open loop voltage gain
(V7-4/V9-4; V1-2 = 0)
voltage ratio V1-2/V9-4
frequency response (3 dB)
current gain (IO/Idiff)
current gain drift as a function of
temperature
signal bias current
flyback supply current
power supply ripple rejection
DC input voltage
common mode input voltage
input bias current
common mode output current
Guard circuit
IO
output current
VO(guard)
output voltage on pin 8
allowable voltage on pin 8
80

dB

0
40
5000


dB
Hz

10-4
K
open loop;



during scan
II(sb) = 0
II(sb) = 0
∆II(sb) = 300 µA (p-p);
fi = 50 Hz; Idiff = 0
not active;
VO(guard) = 0 V
active; VO(guard) = 4.5 V
IO = 100 µA
maximum leakage
current = 10 µA;
50



0


400

80
2.7

0.1
0.2
500
100


1.6
0.5

µA
µA
dB
V
V
µA
mA


50
µA
2.5
5.5
40
mA
V
V
1





VP = 13.5 V; IO(p-p) = 1.87 A; II(sb) = 400 µA; Idiff(p-p) = 500 µA; VFB = 42 V; tFB = 0.6 ms.
APPLICATION DIAGRAM.
4
KKA8356
• 9-Pin Plastic Power Single-in-Line (SIL-9MPF, SOT 131-2)
24-0.21
4.4
0.15
12-0.18
19.8 0.026
16.8 0.135
3.2 0.15
1
9
2.54
2 0.06
0.4 0.05
0.65 0.05
0.25 M
5