ETC DDX2060

DDX-2000/2060
All-Digital High Efficiency
Power Amplifier
GENERAL DESCRIPTION
FEATURES
• HIGH OUTPUT CAPABILITY
2x35W into 8 Ω @ <1% THD+N
1x70W into 4 Ω @ <1% THD+N
• SINGLE SUPPLY (+9V to +30V)
• HIGH EFFICIENCY, >88%
• DIGITAL VOLUME CONTROL, ANTICLIPPING AND AUTOMATIC MUTE
• THERMAL OVERLOAD AND SHORT
CIRCUIT PROTECTION
BENEFITS
• COMPLETE SURFACE MOUNT DESIGN
• SMALL PACKAGE -NO HEAT SINK
• POWER SUPPLY SAVINGS
• ALL DIGITAL - NO DAC
APPLICATIONS
• DIGITAL POWERED SPEAKERS
• PC SOUND CARDS
• CAR AUDIO
• SURROUND SOUND SYSTEMS
• DIGITAL AUDIO COMPONENTS
The DDX-2000 Controller and DDX-2060 Power
Device is an all-digital stereo amplifier chip set that
can provide up to 35 watts per channel of audio
power at very high efficiency.
The DDX-2000
Controller includes two channels of DDX processing,
digital volume control, mute and special processing to
reduce distortion associated with signal clipping. The
controller accepts standard PCM serial formats and
operates from an external 256*Fs clock or from a
crystal. The DDX-2060 Power Device is a dual
channel Class-D H-Bridge power device that has a
logic interface, integrated bridge driver, high efficiency
MOSFET output transistors and protection circuitry.
The benefits of this system are the all-digital design
that eliminates the need for a digital to analog
converter (DAC) and the high efficiency operation
derived from the use of Apogee's patented damped
ternary pulse width modulation (PWM).
This
approach provides an efficiency advantage over
conventional Class-D designs and up to three times
the efficiency of typical Class A/B amplifiers with
music input signals.
V+
I2S Digital Audio
PWM1
3
LP
Filter
2
Volume
3
Mute
DDX-2000
Controller
PWM2
2
+VL
Reset
Power Down
Left
DDX-2060
Power Device
LP
Filter
Right
Clock
129 Morgan Drive, Norwood MA 02062
1
voice: (781) 551-9450 fax: (781) 440-9528 email: [email protected]
Copyright Apogee Technology, Inc 2000
(All Rights Reserved)
November 2001
DOC #1000002-09
____________
DDX-2000/2060
Absolute Maximum Ratings [1]
DDX-2000
SYMBOL
VL
Note [2]
Tstg
PARAMETER
Power supply voltage
Logic Inputs
Storage temperature range
DDX-2060
SYMBOL
VCC
VL
Tj
Tstg
VALUE
UNIT
-0.3V to +4.6V
-0.3V to +6.0V
-40 to +150
V
V
°C
VALUE
UNIT
40V
5.5V
-40 to +150
-40 to +150
V
V
°C
°C
PARAMETER
Power supply voltage
Input logic reference
Operating junction temperature range
Storage temperature range
Recommended Operating Conditions [3]
DDX-2000
SYMBOL
VL
VIH
VIL
Fs
TA
Note 2
DDX-2060
SYMBOL
VCC
VL
VIH
VIL
IOL
TA
PARAMETER
Power supply voltage
Logic inputs, High
Logic inputs, Low
PCM Input Sample Rate
Ambient Temperature
PARAMETER
Power supply voltage
Input logic reference
Logic inputs, High
Logic inputs, Low
Output Sink current, open-drain FAULT and TWARN
Ambient Temperature
MIN
TYP
MAX
UNIT
5.5
0.8
48
70
V
V
V
KHz
°C
MAX
UNIT
28.0
70
V
V
V
V
mA
°C
MAX
UNIT
110
°C/W
MAX
UNIT
2.5
°C/W
°C
°C
3.3
2.0
32
0
MIN
TYP
10.0
3.3
1.7
0.8
1
0
Thermal Data
DDX-2000
SYMBOL
θJA
DDX-2060
SYMBOL
θJC
Tj
Th
PARAMETER
MIN
TYP
Thermal resistance junction-ambient
PARAMETER
Thermal resistance junction-case (thermal pad)
Thermal shut-down junction temperature
Thermal shut-down hysteresis
MIN
TYP
150
25
1. Permanent device damage may occur if ABSOLUTE MAXIMUM RATINGS are exceeded. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2. SCLK, SDATA, LRCLK, VMODE, VCLK/UP, VDATA/DN, SMODE, nRST, ACE, MUTE are 5V input tolerant.
3. Performance not guaranteed beyond recommended operating conditions.
2
Details are subject to change without notice.
____________
DDX-2000/2060
Electrical Characteristics[1]
Refer to circuit Fig. 5. VCC=28V, f=1kHz, TA=25C, RL=8 Ω, and measurement bandwidth 22kHz.
SYMBOL PARAMETER
CONDITION
MIN
TYP MAX
UNIT
Po
IL
IPD
IQ
Output power
Overvoltage Protection Threshold
Undervoltage Protection Threshold
VL supply current for DDX-2000
Vcc supply current in Powerdown
Vcc quiescent current (Hi-Z State)
Icc
Vcc supply current
Isc
Short circuit current limit
THD+N
Total Harmonic Distortion+Noise
SNR
η
Signal-to-Noise Ratio
Efficiency
PSRR
Power Supply Rejection Ratio
THD+N <1%
30
VL= +3.3V
Hi-Z State
2-Chan. switching at
384KHz.
9
100
3
68
3.0
Po=1.0 Wrms
Po= 30 Wrms
A-weighted
Po=2 x 20W
Vrip= 1 Vrms, 120Hz,
-60 db Input
35
35
7
90
1
26
5.0
.08
.33
93
87
60
Wrms
V
V
mA
mA
mA
mA
6.5
.18
.50
A
%
dB
%
dB
1. Characteristics are for the DDX-2060 power device driven by DDX-2000 processor.
3
Details are subject to change without notice.
____________
DDX-2000/2060
DDX-2000 Pin Function Description
Audio Serial Interface (I2S)
Pin Name
Pin No.
Description
SCLK [1]
1
Input serial clock
SDATA [1]
2
Input serial data
LRCLK [1, 2]
3
Input Left/Right
SMODE [1, 2]
20
Serial Mode Select (0=Left Justified, 1= I2S. See Figure 3)
Gain/Volume Interface
Pin Name
Pin No.
Description
VMODE [1, 2]
39
Volume Mode Select
VCLK/UP [1, 2]
40
Volume Data Clock or Increment Up
VDATA/DN [1, 2]
41
Volume Serial Data In or Increment Down
ACE [1, 2]
5
Anti-Clipping Enable, Active Hi
System Clocking
Pin Name
Pin No.
Description
XI
11
256*fs Oscillator/External 256*fs clock input
XO
10
256*fs Oscillator
INLP
16
PLL Filter
OUTLP
17
PLL Filter
DDX Output Signals/Control
Pin Name
Pin No.
Description
MUTE [1, 3]
38
Active Hi, sets outputs to damped state
OUTLA
33
Left channel output A
OUTLB
32
Left channel output B
OUTRA
26
Right channel output A
OUTRB
25
Right channel output B
Power Supplies/Miscellaneous
Pin Name
Pin No.
Description
VL
4, 13, 15, 27,
29, 44
Power
GND
9, 12, 14, 18,
19, 28, 34, 35,
37, 42, 43
6, 7
Ground
nRST [1, 2, 4]
NC
1.
2.
3.
4.
8, 21, 22, 23,
24, 30, 31, 36
System Reset, active low. Both pins must be connected for
proper operation.
No Connect. Must be left open.
Denotes 5V input tolerance.
Denotes 50k internal pullup.
Denotes 50k internal pulldown.
Denotes TTL Schmitt Input Buffer. Vt+ = 2.0V max. Vt- = 0.7V min. Typical hysteresis is 0.5V.
4
Details are subject to change without notice.
____________
DDX-2000/2060
DDX 2060 Pin Function Description
PWM Inputs
Pin No.
29
Description
Left A logic input signal
INLB
Left B logic input signal
INRA
Right A logic input signal
INRB
Right B logic input signal
Control/Miscellaneous
Pin Name
Description
PWRDN
Power Down (0=Shutdown, 1= Normal).
TRI-
26
FAULT [1]
27
TWARN [1]
28
Tri-
TS Hi-
CONFIG [3]
(0=Warning IC >= 130°C, 1=Normal).
Configuration (0=Normal, 1=Parallel operation for mono).
NC
Do not connect.
Power O
Pin Name
Pin No.
OUTPL
16, 17
OUTNL
10, 11
OUTPR
8, 9
OUTNR
2, 3
Pin Name
Pin No.
VCC[1P, 1N, 2P, 2N]
4, 7, 12, 15
PGND[1P, 1N, 2P, 2N]
5, 6, 13, 14
VREG1
21, 22
VREG2
33, 34
VSIG
35, 36
1.
2.
Positive supply.
23
Logic reference voltage.
19
Logic reference ground.
1
20
Substrate ground.
Internal regulator ground.
-drain.
ase with the input.
Connect CONFIG Pin 24 to VREG1 Pins 21,22 to implement parallel operation for mono.
5
Details are subject to change without notice.
____________
DDX-2000/2060
FIG. 5A - Typical Application Circuit (Signal Processing section)
6
Details are subject to change without notice.
-2000/2060
FIG. 5B - Typical Application Circuit (Power section)
7
____________
DDX-2000/2060
Typical Performance Characteristics
at Vcc = 28V, 8 Ohm load.
Fig 6: Efficiency vs Output Power
Fig 7: Frequency response
100
80
Efficiency %
+1
+1
+0.5
+0.5
60
d
B
r
40
C
H
1
d
B
r
-0
-0
C
H
2
-0.5
-0.5
20
0
-1
20
0
5
10
15
20
25
-1
50
100
200
30
500
1k
2k
5k
10k 20k
Hz
Output Power W
Fig 8: THD+N vs Frequency
Fig 9: THD+N vs Outpwr at 1 KHz
(w/ ANTICLIPPING DISABLED)
20
1
10
0.5
5
0.2
T
H
D
+
N
2
1W
T
H
D
+
N
0.1
0.05
%
%
1
0.5
0.2
0.1
0.02
10W
0.05
0.01
0.02
0.006
20
50
100
200
500
Hz
1k
2k
5k
10k 20k
0.01
10m 20m
50m 100m
500m
1
2
5
10
20
50
W rms
8
Details are subject to change without notice.
____________
DDX-2000/2060
Typical Performance Characteristics
at Vcc = 24V, 4 Ohm load.
Fig 11: THD+N vs Outpwr at 1 KHz
Fig 10: THD+N vs Frequency
(w/ ANTICLIPPING DISABLED)
20
1
10
0.5
5
0.2
T
H
D
+
N
2
1W
T
H
D
+
N
0.1
0.05
10W
1
0.5
0.2
%
%
0.1
0.02
0.05
0.01
0.02
0.006
20
50
100
200
500
1k
2k
5k
10k
0.01
10m 20m
20k
50m 100m
500m
Hz
1
2
5
10
20
60
W rms
Typical Performance Characteristics
at Vcc = 28V, 4 Ohm load,
configured for Mono.
Fig 12: THD+N vs Frequency
Fig 13: THD+N vs Outpwr at 1 KHz
(w/ ANTICLIPPING DISABLED)
1
20
10
0.5
5
0.2
2
2W
T
H
D
+
N
0.1
%
0.05
1
0.5
0.2
%
20W
0.1
0.02
0.05
0.01
0.02
0.006
20
50
100
200
500
Hz
1k
2k
5k
10k 20k
0.01
100m
200m
500m
1
2
5
10
20
50
100
W rms
9
Details are subject to change without notice.
____________
DDX-2000 utilizes serial data words of 16 bits
and accepts data words up to 24 bits.
SYSTEM OVERVIEW
The DDX-2000/2060 is an all-digital 2-channel
amplifier chip set that delivers up to 35 watts per
channel at very high efficiency. The system
consists of a DDX-2000 Controller, DDX-2060
Power Device and an output filter. The DDX2000 Controller accepts standard digital audio
data and converts it to PWM logic level signals.
The device also includes digital volume, muting
and anti-clipping functions. The DDX-2060 is a
dual channel H-Bridge that converts DDX-2000
PWM timing signals to power at the load. A
passive low pass filter prior to the load
attenuates the modulation carrier. The DDX2060 is protected against over-voltage, thermal
and short circuit conditions.
DDX-2000 CONTROLLER
The DDX-2000 Controller is a 3.3V digital
integrated circuit that converts serial PCM digital
audio signals into Apogee's patented damped
ternary outputs.
The device supports two
modes of digital volume control, mute and anticlipping functions. A block diagram of the
device is shown in Figure 1.
ACE
SCLK
SDATA
SERIAL
INTERFACE
LRCLK
MUTE
OUTL[1:2]
ANTICLIPPING
PWM
GENERATION
VMODE
VCLK/UP
VDATA/DN
VOLUME/
GAIN
SYSTEM
CLOCKING
DDX-2000/2060
OUTR[1:2]
XI XO LPIN LPOUT
Figure 1 - DDX-2000 Functional Diagram
Audio Serial Interface
The DDX-2000 audio serial input was designed
to interface with standard digital audio
components such as S/PDIF receivers, surround
sound decoders and digital signal processors.
Serial data input is controlled by three input pins:
serial clock (SCLK), serial data (SDATA), and
left/right clock (LRCLK) in either I2S or left
justified formats as controlled by the serial mode
pin (SMODE). The serial data formats and
timing diagram are shown in Figure 3. The
Volume Interface
The volume level of the DDX2000 PWM outputs
can be adjusted by setting the left and right
volume registers (VOLL and VOLR). These
registers are seven bits with a step size of
approximately -0.75 dB providing an adjustment
range of –82.5 dB to +12.0 dB. Table 1 shows
the volume level as a function of the register
values. Following power-on-reset both volume
registers are set to 0x26 or -15.75 dB.
The volume registers, VOLL and VOLR, can be
set with a serial data load using a microcontroller or similar device (serial mode) or by
incrementing the volume register using control
pins (toggle mode). This functionality is
controlled using the volume mode select pin
(VMODE) and two multifunction pins; volume
clock/volume up (VCLK/UP) and the volume
data/volume down (VDATA/DN).
Table 1 – Volume Control
Volume Register
(VOLL, VOLR)
hexadecimal
0x00, 0x80
0x01, 0x81
0x02, 0x82
...
0x10, 0x90
0x11, 0x91
0x12, 0x92
...
0x7e, 0xfe
0x7f, 0xff
Volume
(dB)
+12.0
+11.25
+10.5
...
0.0
-0.75
-1.5
...
-82.5
Mute
When the VMODE is logic-high (internally
pulled-up) the device operates in toggle mode.
The volume registers (both VOLL and VOLR)
can be incremented either up or down by
bringing the inputs VCLK/UP or VDATA/DN low.
The volume register will increment at
approximately 5 steps per second, for the first
1.4 seconds and then increase to approximately
10 steps per second until the upper or lower
volume limits are reached or the input is
released.
A serial mode volume change is initiated by
bringing VMODE pin low. Serial data is input on
10
Details are subject to change without notice.
____________
VDATA/DN and is latched on the rising edge of
the VCLK/UP input as shown in Figure 4. After
all eight bits are received VMODE must be
brought high to latch the volume register. Note,
each channel volume register must be written
independently, (see Table 1).
DDX-2000/2060
mute function which is activated upon receipt of
2048 consecutive zero data words on both the
left and right serial inputs. Automatic transition
from mute will occur on the first non-zero input
word.
DDX-2060 POWER DEVICE
For applications that provide digital volume
control prior to the DDX-2000, the attenuation
register can be set to 0 dB by pulling both the
VCLK/UP and VDATA/DN to ground, leaving
VMODE high.
The DDX-2000 includes an anti-clipping function
to improve audio quality when using the internal
volume control set to greater than 0 dB. This
function dynamically adjusts the volume level to
significantly reduce distortion associated with
signal clipping. This function is enabled by
setting the anti-clipping enable (ACE) pin high.
When enabled, the maximum distortion will be
limited regardless of the volume. For
applications where maximum power is desired,
the ACE may be disabled and the output power
and distortion will increase for volume settings
which exceed 0 dB.
The DDX-2060 Power Device is a dual channel
H-Bridge that can deliver over 35 watts per
channel of audio output power. The DDX-2060
includes; a logic interface, integrated bridge
drivers, high efficiency MOSFET outputs and
protection circuitry. Two logic level signals per
channel are used to control high-speed
MOSFET switches to connect the speaker load
to the input supply or to ground in a bridge
configuration, according to Apogee's patented
damped ternary PWM. The DDX-2060 includes
over-current,
thermal,
and
over-voltage
protection and under-voltage lockout with
automatic recovery. A thermal warning status is
also provided.
INL[1:2]
INR[1:2]
System Clocking
The DDX-2000 operates from a master clock
source whose frequency is 256 times the input
LRCLK sample rate (256*fs). The device can
accommodate sample rates from below 32 kHz
to above 48 kHz. Either external clock sources
or the built in oscillator may be used.
In designs that recover the clock (e.g., S/PDIF),
the 256*fs output can be utilized for the master
system clock to provide synchronous operation.
For systems that operate asynchronously, i.e.,
the crystal clock is not exactly matched to the
incoming serial data stream, the DDX-2000 will
automatically accommodate sample frequency
mismatch up to 0.2 %.
The accuracy of the master input clock will
determine amplifier system performance. To
meet the specified performance, random clock
jitter must be less than 400pS p-p.
DDX Output Control
Asserting the MUTE input (logic-high), the DDX2000 will command the zero state (load
damping)
which short-circuits the load to
ground. The device also includes an automatic
VL
OUTPL
Logic I/F
and Decode
Left
H-Bridge
PWRDN
OUTNL
TRI-STATE
FAULT
TWARN
Protection
Circuitry
OUTPR
Right
H-Bridge
Regulators
OUTNR
Figure 2 - DDX-2060 Block Diagram
Logic Interface and Decode
The DDX-2060 power outputs are controlled
using two logic level timing signals. In order to
provide a proper logic interface, the VL input
must operate from the DDX-2000 logic supply.
Protection Circuitry
The DDX-2060 includes protection circuitry for
over-current, over-voltage, and thermal overload
conditions. A thermal warning pin TWARN is
activated low (open-drain MOSFET) when the IC
temperature exceeds 130°C, in advance of the
thermal shutdown protection. When a fault
condition is detected (logical OR of over-current,
over-voltage, and thermal), an internal fault
11
Details are subject to change without notice.
____________
signal acts to immediately disable the output
power MOSFETs, placing both H-bridges in a
high impedance state. At the same time an
open-drain MOSFET connected to the FAULT
pin is switched on. There are two possible
modes subsequent to activating a fault. The first
is a SHUT-DOWN mode. With FAULT (pull-up
resistor) and TRI-STATE pins independent, an
activated fault will disable the device, signaling
low at the FAULT output. The device may
subsequently be reset to normal operation by
toggling the TRI-STATE pin from High-Low-High
using an external logic signal. The second is an
AUTOMATIC recovery mode. This is depicted
in the application circuit, Figure 5B. The FAULT
and TRI-STATE pins are shorted together and
connected to a time constant circuit comprising
R6 and C17. An activated FAULT will force a
reset on the TRI-STATE pin causing normal
operation to resume following a delay
determined by the time constant of the circuit. If
the fault condition is still presented, the circuit
operation will continue repeating until such time
as the fault condition is removed. An increase in
the time constant of the circuit will produce a
lower recovery frequency tending toward safer
operation. Note, the automatic recovery mode
may produce audible artifacts in a loudspeaker
when a fault is activated. Care must be taken in
the overall system design so as not to exceed
the protection thresholds under normal
operation.
Power Outputs
The DDX-2060 power and output pins are
duplicated to provide a low impedance path for
the devices bridged outputs.
All duplicate
power, ground and output pins must be
connected for proper operation. The PWRDN or
TRI-STATE pins should be used to set all
MOSFETS to the Hi-Z state during power-up
until the logic power supply, VL, is well
established.
Parallel Output/High Current Operation
The DDX-2060 outputs can be connected in
parallel for mono operation to increase the
output current to a load. In this configuration the
device can provide over 70W into 4 Ω. This
mode is enabled with the CONFIG pin
connected to VREG1 and the inputs combined
INLA=INLB, INRA=INRB and outputs combined
OUTLA=OUTLB, OUTRA=OUTRB.
DDX-2000/2060
ADDITIONAL INFORMATION
Output Filter
A passive two-pole low pass filter is used on the
DDX-2060 power outputs to reconstruct the
audio signal. System performance can be
significantly affected by the output filter design
and choice of components.
Good audio
performance can be obtained with low cost,
solenoid type inductors having a DCR <.05 Ω
and a 2A minimum rating.
Output filter
capacitors should be the following types:
Common-mode capacitors should be 50V
ceramic, X7R dialetric or 50V film types.
Differential capacitors should be 50V or greater
film types. A filter design for 8 Ω loads is shown
in the Typical Application Circuit Fig. 5B for
reference.
Power Dissipation/Heat Sink Requirements
The DDX-2060 is a high efficiency dual channel
design intended for audio applications up to 35
Watts per channel. The power dissipation of the
device will depend primarily on the supply
voltage, load impedance, and output modulation
level.
The DDX-2060 surface mount package includes
an exposed thermal pad on the bottom of the
device to provide a direct thermal path from the
integrated circuit to the PCB. This pad must be
soldered to a low thermal impedance path at
circuit ground potential for proper operation, e.g.
a PCB ground plane. For continuous duty rated
applications, careful consideration must be
made to the overall thermal design.
Performance Measurements
Class D amplifiers produce measurable
switching distortion outside the audio bandwidth.
Apogee's DDX amplifier uses patented PWM
modulation that significantly reduces the size of
these products compared to typical Class D
designs. However, in order to obtain accurate
performance measurements in the audio
bandwidth (i.e., 20Hz to 20kHz) additional
filtering is required. The Typical Performance
data was taken using a brick wall filter with a
break frequency of 20kHz. This type of filter is
often provided with audio measurement
systems.
12
Details are subject to change without notice.
____________
DDX-2000/2060
INTERFACE TIMING
2
SMODE=1 I S
Left
LRCLK
Right
SCLK
MSB
SDATA
LSB
MSB
LSB
MSB
SMODE=0 Left Justified
Left
LRCLK
Right
SCLK
SDATA
MSB
LSB
MSB
LSB
MSB
Figure 3 - Audio Serial Interface
VMODE
E
A
CH
VDATA
B
D6
D5
C
D4
D3
D2
D1
D0
D
D
VCLK
Notes:
A) VDATA hold time from VMODE > 75 ns
B) VCLK hold time from VMODE > 75 ns
C) VDATA setup to VCLK > 50 ns
D) VDATA hold from VCLK > 25 ns
E) VDATA setup to VMODE > 75 ns
F) VCLK HIGH TIME, CLK LOWTIME > 100 ns
G) CH = Channel select. Left=0, Right=1.
H) Volume register (MSB=D6, LSB=D0).
Figure 4 - Serial Volume Load Timing
13
Details are subject to change without notice.
____________
DDX-2000/2060
PHYSICAL DIMENSIONS
Dimensions shown in mm
a2
A
e
a1
DETAIL B
DETAIL A
E
DETAIL A
lead
D
slug
a3
36
19
E1
E2
DETAIL B
0.35
1
18
Gage
Plane
S
L
h x 45
N
N
DIM.
mm
TYP.
MIN.
A
MAX.
MIN.
inch
TYP.
3.60
a1
a2
a3
0.10
b
c
D (1)
D1
E
MAX.
0.141
0.004
0
0.30
3.30
0.10
0
0.012
0.130
0.004
0.22
0.23
0.38
0.32
0.008
0.009
0.015
0.012
15.80
9.40
13.90
16.00
9.80
14.50
0.622
0.370
0.547
0.630
0.385
0.570
e
e3
0.65
11.05
E1 (1) 10.90
E2
E3
5.80
0.0256
0.435
0.228
0.437
0.114
0.244
E4
G
2.90
0
3.20
0.10
0.114
0
0.126
0.004
H
h
L
15.50
15.90
1.10
1.10
0.610
0.626
0.043
0.043
N
S
0.80
1
8
11.10
2.90
6.20
0.429
0.031
0°(max.)
°(max.)
(1): "D" and "E1" do not include mold flash or protrusions
- Mold flash or protrusions shall not exceed 0.15mm (0.006 inch)
- Critical dimensions are "a3", "E" and "G".
DDX-2060 - 36 Pin Power Package
14
Details are subject to change without notice.
____________
DDX-2000/2060
PHYSICAL DIMENSIONS
Dimensions shown in mm
Mirror finish
DDX-2000 - 44 Pin Quad Plastic Flat Package
Information furnished in this publication is believed to be accurate and reliable. However, Apogee Technology, Inc. assumes no
responsibility for its use, or for any infringements of patents or other rights of third parties that may result form its use. Specifications
in this publication are subject to change without notice. This publication supersedes and replaces all information previous supplied.
 Apogee Technology, Inc. All Rights Reserved
15
Details are subject to change without notice.