ZL40167/DCB [MICROSEMI]

Operational Amplifier, 2 Func, 4200uV Offset-Max, PDSO8, 0.150 INCH, MS-012AA, SOIC-8;
ZL40167/DCB
型号: ZL40167/DCB
厂家: Microsemi    Microsemi
描述:

Operational Amplifier, 2 Func, 4200uV Offset-Max, PDSO8, 0.150 INCH, MS-012AA, SOIC-8

放大器 光电二极管
文件: 总32页 (文件大小:818K)
中文:  中文翻译
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ZL40167  
High Output Current  
High Speed Dual Operational Amplifier  
Data Sheet  
September 2003  
Features  
High Output Drive  
Ordering Information  
18.8 Vpp differential output voltage, RL = 50Ω  
9.4 Vpp single-ended output voltage, RL = 25Ω  
ZL40167/DCA (tubes) 8 lead SOIC  
ZL40167/DCB (tape and reel) 8 lead SOIC  
High Output Current  
± 200mA @ Vo = 9.4 Vpp, Vs = 12V  
Low Distortion  
-40°C to +85°C  
High ESD (Electro-Static Discharge) immunity  
4kV for Supply and Output pins  
Low differential gain and phase  
0.005% and -0.07deg  
85dB SFDR (Spurious Free Dynamic Range)  
@ 100KHz, Vo = 2Vpp, RL = 25Ω  
High Speed  
192MHz 3dB bandwidth (G=2)  
240V / µs slew rate  
Applications  
Low Noise  
ADSL PCI modem cards  
xDSL external modem  
Line Driver  
3.8nV / Hz: input noise voltage  
2.7pA / Hz: input noise current  
Low supply current: 7mA/amp  
Single-supply operation: 5V to 12V  
8
7
6
5
Out_1  
V+  
1
In_n_1  
In_p_1  
V -  
Out_2  
In_n_2  
In_p_2  
2
3
4
1
2
ZL40167  
Figure 1 - Functional Block Diagram and Pin Connection  
1
Zarlink Semiconductor Inc.  
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.  
Copyright 2003, Zarlink Semiconductor Inc. All Rights Reserved.  
ZL40167  
Data Sheet  
Description  
The ZL40167 is a low cost voltage feedback opamp capable of driving signals to within 1V of the power supply rails.  
It features low noise and low distortion accompanied by a high output current which makes it ideally suited for the  
application as an xDSL line driver. The dual opamp can be connected as a differential line driver delivering signals  
up to 18.8Vpp swing into a 25load, fully supporting the peak upstream power levels for upstream full-rate ADSL  
(Asymmetrical Digital Subscriber Line).  
The wide bandwidth, high power output and low differential gain and phase figures make the ZL40167 ideally suited  
for a wide variety of video driver applications.  
Application Notes  
The ZL40167 is a high speed, high output current, dual operational amplifier with a high slew rate and low  
distortion. The device uses conventional voltage feedback for ease of use and more flexibility. These characteristics  
make the ZL40167 ideal for applications where driving low impedances of 25 to 100such as xDSL and active  
filters.  
The figure below shows a typical ADSL application utilising a 1:2 transformer, the feedback path provides a  
Gain = +2.  
12R5  
Rf1  
Rg  
100R  
Rf2  
12R5  
Figure 2 - A Typical ADSL Application  
A class AB output stage allows the ZL40167 to deliver high currents to low impedance loads with low distortion  
while consuming low quiescent current.  
Note: the high ESD immunity figure of 4kV may mean that in some designs fewer additional EMC protection  
components are needed thus reducing total system costs.  
The ZL40167 is not limited to ADSL applications and can be used as a general purpose opamp configured with  
either inverting or non-inverting feedback. The figure below shows non-inverting feedback arrangement that has  
typically been used to obtain the data sheet specifications.  
2
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Rf  
Rg  
Figure 3 - A Non-Inverting Feedback Amplifier Example  
Video transmitter and receiver for twisted wire pair  
Composite video signals can be transmitted down twisted pair cable, i.e. Ethernet (CAT 5), using a differential  
transmitter and receiver. The transmitter must be able to drive high currents into the low impedance twisted pair  
cable. For video, the amplifiers require flat gain and low phase-shift over the video signal band. To ensure this, the  
amplifiers will have 3dB bandwidths well in excess of this. The ZL40167 (dual amplifier) has all of these attributes.  
With reference to the differential video driver shown in Figure , the input coax is assumed to have a characteristic  
impedance of 75 Ohms, this is terminated with a parallel combination of 110 Ohms and the input impedance of  
amplifier IC1 (b) of 255 Ohms, giving 77 Ohms. Low values of feedback resistors are used around the op-amps to  
reduce phase-shift due to parasitic capacitors and to minimise the addition of noise.  
Baseband PAL or NTSC video signals generally have an amplitude of 2V pk-pk. A gain of two is used to ensure that  
the signal level at the end of the (terminated with 100 Ohms) differential pair will be the same as the input level,  
neglecting any losses due to the use of long cable lengths.  
Composite Video  
Co-Ax Input  
IC1(a)  
50R  
50R  
110R  
510R  
510R  
510R  
510R  
510R  
Twisted Pair  
Output  
IC1(b)  
Figure 4 - Differential Video Driver  
The differential receiver is shown in Figure 5 has a 100 Ohm line termination resistor, followed by a differential  
amplifier. Long cables will tend to attenuate the signal with greater losses at the higher frequencies, so the second  
amplifier is used to equalise these losses. Initially the amplifier should be built without fitting components R1 and  
3
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
C1. Select the value of R2 to give the required gain at low frequency. Adjust the values of R1 and C1 to correct for  
the frequency dependant attenuation of the cable.  
To drive a coax cable the output of the amplifier is connected via a series matching 75 Ohm resistor, again this  
second (dual amplifier) ZL40167 provides the required power output for the restored 2Vpk-pk video signal.  
510R  
510R  
IC2(a)  
Twisted Pair  
100R  
Input  
510R  
510R  
R2  
Composite Video  
C1  
R1  
Co-Ax Output  
IC2(b)  
75R  
510R  
Figure 5 - Differential Video Receiver  
4
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Absolute Maximum Ratings - (See Note 1)  
Parameter  
Symbol  
Min  
Max  
Units  
Vin Differential  
V
±1.2  
V
IN  
Output Short Circuit Protection  
V
See Apps  
Note in this  
data sheet  
OS/C  
Supply Voltage  
V+, V-  
±13.2  
(V+) +0.8  
±5.5  
V
V
Voltage at Input Pins  
Voltage at Output Pins  
V
, V  
(V-) -0.8  
(+IN)  
(-IN)  
V
V
O
ESD Protection (HBM Human Body Model)  
(See Note 2)  
4
(Note 3)  
kV  
Storage Temperature  
Latch-up test  
-55  
+150  
°C  
+/-100mA  
for 100ms  
(Note 4)  
Supply transient test  
20% pulse  
for 100ms  
(Note 5)  
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate  
conditions for which the device is intended to be functional, but specific performance is not guaranteed. For guaranteed  
specifications and the test conditions, see the Electrical Characteristics.  
Note 2: Human body model, 1.5kin series with 100pF. Machine model, 200in series with 100pF.  
Note 3: 1.25kV between the pairs of +INA, -INA and +INB, -INB pins only. 4kV between supply pins, OUTA or OUTB pins and any  
input pin.  
Note 4: +/-100mA applied to input and output pins to force the device to go into “latch-up”. The device passes this test to JEDEC spec  
17.  
Note 5: Positive and Negative supply transient testing increases the supplies by 20% for 100ms.  
Operating Ratings - (See Note 1)  
Parameter  
Symbol  
Min  
Max  
Units  
Supply Voltage  
V+, V-  
± 2.5  
-40  
±6.5  
V
Junction Temperature Range  
Junction to Ambient Resistance  
150  
°C  
Rth(j-a)  
Rth(j-c)  
150  
°C  
4 layer FR5  
board  
Junction to Case Resistance  
60  
°C  
4 layer FR5  
board  
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate  
conditions for which the device is intended to be functional, but specific performance is not guaranteed. For guaranteed  
specifications and the test conditions, see the Electrical Characteristics.  
5
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Electrical Characteristics - TA = 25°C, G = +2, Vs = ± 6V, Rf = Rg = 510, RL = 100/ 2pF; Unless  
otherwise specified.  
Min  
Typ  
Max  
Test  
Type  
Symbol  
Parameter  
Conditions  
Units  
(Note 1) (Note 2) (Note 3)  
Dynamic Performance  
-3dB Bandwidth  
Vo = 200mVp-p  
192  
32  
MHz  
MHz  
V/µs  
ns  
C
C
C
C
C
-0.1dB Bandwidth  
Slew Rate  
Vo = 200mVp-p  
4V Step O/P, 10-90%  
4V Step O/P, 10-90%  
240  
13.3  
1.7  
Rise and Fall Time  
Rise and Fall Time  
200mV Step O/P,  
10-90%  
ns  
Differential Gain  
NTSC, RL = 150Ω  
NTSC, RL = 150Ω  
0.005  
-0.07  
%
C
C
Differential Phase  
deg  
Distortion and Noise Response  
nd  
2
Harmonic  
Vo = 8.4Vpp,  
-65.4  
-83.8  
-93.6  
-86  
dBc  
dBc  
dBc  
dBc  
dBc  
dBc  
dBc  
dBc  
C
C
C
C
C
C
C
C
Distortion  
f =100KHz,RL= 25/2pF  
Vo = 8.4Vpp,  
f =1MHz,RL = 100/2pF  
Vo = 2Vpp,  
f =100kHz,RL= 25/2pF  
Vo = 2Vpp,  
f =1MHz,RL =100/2pF  
rd  
3
Harmonic  
Vo = 8.4Vpp,  
-70  
Distortion  
f =100KHz,RL=25/2pF  
Vo = 8.4Vpp,  
-77.7  
-85  
f =1MHz,RL =100/2pF  
Vo = 2Vpp,  
f =100KHz,RL=25/2pF  
Vo = 2Vpp,  
-73.5  
f =1MHz,RL=100/2pF  
MTPR  
Multi-Tone Power  
Ratio  
47.4375 KHz  
69 KHz  
-75  
-76.3  
-73.8  
-71.5  
3.85  
2.7  
dBc  
dBc  
C
C
C
C
C
C
90.5625 KHz  
112.125 KHz  
dBc  
dBc  
Input Noise Voltage f = 100KHz  
Input Noise Current f = 100KHz  
nV/Hz  
pA/Hz  
6
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Min  
Typ  
Max  
Test  
Type  
Symbol  
Parameter  
Conditions  
Units  
(Note 1) (Note 2) (Note 3)  
Input Characteristics  
Vos  
Ib  
Input Offset Voltage Tj = -40°C to 150°C  
Input Bias Current Tj = -40°C to 150°C  
Input Offset Current Tj = -40°C to 150°C  
- 4.2  
- 0.3  
-10  
4.2  
-20  
2
mV  
µA  
µA  
V
A
A
A
A
Ios  
-2  
-0.2  
CMVR  
Common Mode  
Voltage Range  
Tj = -40°C to 150°C  
- 4.9  
4.9  
CMRR  
Common Mode  
Rejection Ratio  
Tj = -40°C to 150°C  
70  
79  
10  
dB  
A
Transfer Characteristics  
Avol  
Voltage Gain  
RL = 1k,  
4.7  
V/mV  
A
Tj = -40°C to 150°C  
RL = 25,  
1.6  
- 4.5  
- 5  
5.5  
A
A
A
B
Tj = -40°C to 150°C  
Output Swing  
Output Swing  
RL = 25,  
± 4.7  
± 5.1  
1000  
4.5  
5
V
V
Tj = -40°C to 150°C  
RL = 1k,  
Tj = -40°C to 150°C  
Isc  
Output Current  
(Note 3)  
Vo = 0,  
570  
mA  
Tj = -40°C to 150°C  
Power Supply  
Is  
Supply  
Tj = -40°C to 150°C  
Tj = -40°C to 150°C  
7
9
mA  
dB  
A
A
Current / Amp  
PSRR  
Power Supply  
Rejection Ratio  
73  
81  
Note 1: The maximum power dissipation is a function of Tj(max), θJA and TA. The maximum allowable power dissipation at any  
ambient temperature is PD = (Tj(max) - TA)/ θJA. All numbers apply for packages soldered directly onto a PC board.  
Note 2: Typical values represent the most likely parametric norm.  
Note 3: Test Types:  
a. 100% tested at 25°C. Over temperature limits are set by characterisation, simulation and statistical analysis.  
b. Limits set by characterisation, simulation and statistical analysis.  
c. Typical value only for information.  
7
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
± 2.5V Electrical Characteristics - TA = 25°C, G = +2, Vs = ± 2.5V, Rf = Rg = 510, RL = 100/ 2pF; Unless  
otherwise specified.  
Min  
(Note 1)  
Typ  
Max  
Test  
Type  
Symbol  
Parameter  
Conditions  
Units  
(Note 2) (Note 3)  
Dynamic Performance  
-3dB Bandwidth  
176.5  
83.8  
216  
3.7  
MHz  
MHz  
V/µs  
ns  
C
C
C
C
C
-0.1dB Bandwidth  
Slew Rate  
1V Step O/P, 10-90%  
1V Step O/P, 10-90%  
Rise and Fall Time  
Rise and Fall Time  
200mV Step O/P,  
10-90%  
1.7  
ns  
Distortion and Noise Response  
nd  
2
Harmonic  
Vo = 2Vpp,f = 100KHz,  
-92.6  
-85  
dBc  
dBc  
dBc  
dBc  
C
C
C
C
Distortion  
RL = 25Ω  
Vo = 2Vpp, f = 1MHz,  
RL = 100Ω  
rd  
3 Harmonic  
Vo = 2Vpp, f = 100KHz,  
-86.3  
-74.8  
Distortion  
RL = 25Ω  
Vo = 2Vpp, f = 1MHz,  
RL = 100Ω  
Input Characteristics  
Vos  
Ib  
Input Offset Voltage Tj = -40°C to 150°C  
- 4.2  
- 0.3  
- 10  
4.2  
-20  
mV  
µA  
V
B
B
B
Input Bias Current  
Tj = -40°C to 150°C  
CMVR  
Common Mode  
Voltage Range  
-1.55  
70  
1.55  
CMRR  
Common Mode  
Rejection Ratio  
Tj = -40°C to 150°C  
80  
dB  
B
Transfer Characteristics  
Avol Voltage Gain  
RL = 1k, Tj = -40°C to  
150°C  
5.5  
1.6  
10.5  
5.8  
V/mV  
B
B
RL = 25, Tj = -40°C to  
150°C  
Output Characteristics  
Output Swing  
RL = 25, Tj = -40°C to  
150°C  
-1.4  
-1.6  
±1.45  
±1.65  
1.4  
1.6  
V
B
B
RL = 1k, Tj = -40°C to  
150°C  
8
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Min  
(Note 1)  
Typ  
Max  
Test  
Type  
Symbol  
Parameter  
Conditions  
Units  
(Note 2) (Note 3)  
Power Supply  
Is  
Supply  
Current/Amp  
Tj = -40°C to 150°C  
Tj = -40°C to 150°C  
6.75  
83  
8.5  
mA  
dB  
A
B
PSRR  
Power Supply  
Rejection Ratio  
73  
Note 1: The maximum power dissipation is a function of Tj(max), θJA and TA. The maximum allowable power dissipation at any  
ambient temperature is PD = (Tj(max) - TA)/ θJA. All numbers apply for packages soldered directly onto a PC board.  
Note 2: Typical values represent the most likely parametric norm.  
Note 3: Test Types:  
a. 100% tested at 25°C. Over temperature limits are set by characterisation, simulation and statistical analysis.  
b. Limits set by characterisation, simulation and statistical analysis.  
c. Typical value only for information.  
9
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100,Vs = 6V. Unless  
otherwise specified.  
Output Swing  
12.0  
10.0  
8.0  
RL = 1K  
6.0  
RL = 25  
4.0  
2.0  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 6 - Output Swing  
Positive Output Swing into 1Kohms  
1.0  
0.9  
0.8  
0.7  
0.6  
0.5  
0.4  
0.3  
0.2  
0.1  
0.0  
- 40 C  
25 C  
85 C  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 7 - Positive Output Swing into 1KΩ  
10  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Negative Output Swing into 1Kohms  
1.0  
- 4 0 C  
0.9  
2 5 C  
0.8  
85 C  
0.7  
0.6  
0.5  
0.4  
0.3  
0.2  
0.1  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 8 - Negative Output Swing into 1KΩ  
Positive Output Swing into 25 ohms  
1.4  
1.2  
1.0  
0.8  
0.6  
0.4  
0.2  
0.0  
-40 C  
25 C  
85 C  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 9 - Positive Output Swing into 25Ω  
11  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Negative Output Swing into 25 ohms  
1.4  
1.2  
25 C  
- 40 C  
1.0  
0.8  
0.6  
0.4  
0.2  
0.0  
85 C  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 10 - Negative Output Swing into 25Ω  
+Vout vs. ILoad  
5.4  
5.3  
5.2  
5.1  
5.0  
4.9  
4.8  
4.7  
4.6  
85 C  
25 C  
- 40 C  
0.00  
0.05  
0.10  
0.15  
0.20  
0.25  
ILoad (A)  
Figure 11 - +Vout vs. lLoad  
12  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
-Vout vs. ILoad  
5.4  
5.3  
5.2  
5.1  
85 C  
5.0  
25 C  
4.9  
- 40 C  
4.8  
4.7  
4.6  
0.00  
0.05  
0.10  
0.15  
0.20  
0.25  
ILoad (A)  
Figure 12 - -Vout vs. lLoad  
+Vout vs. ILoad, VS = 2.5V  
2.0  
1.9  
1.8  
1.7  
1.6  
1.5  
1.4  
1.3  
1.2  
1.1  
1.0  
25 C  
85 C  
- 40 C  
0.00  
0.05  
0.10  
0.15  
0.20  
0.25  
ILoad (A)  
Figure 13 - +Vout vs. lLoad, Vs = ±2.5V  
13  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
-Vout vs. ILoad, VS = 2.5V  
2.0  
1.9  
1.8  
2 5 C  
1. 7  
8 5 C  
1.6  
1. 5  
1.4  
- 4 0 C  
1.3  
1.2  
1.1  
1.0  
0.00  
0.05  
0.10  
0.15  
0.20  
0.25  
ILoad (A)  
Figure 14 - -Vout vs. lLoad, Vs ±2.5V  
Vout vs. RLoad  
85 C  
5.5  
5.0  
4.5  
4.0  
3.5  
3.0  
25 C  
-40 C  
0
10  
20  
30  
40  
50  
60  
70  
80  
90  
100  
110  
RLoad (ohms)  
Figure 15 - Vout vs Rload  
14  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Supply Current  
16.0E-3  
25 C  
85 C  
14.0E-3  
12.0E-3  
10.0E-3  
8.0E-3  
- 40 C  
6.0E-3  
4.0E-3  
2.0E-3  
000.0E+0  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 16 - Supply Current vs. Supply Voltage  
Source Current, Vo = 0V  
1.4  
25 C  
1.2  
1.0  
- 40 C  
85 C  
0.8  
0.6  
0.4  
0.2  
0.0  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 17 - Sourcing Current vs. Supply Voltage  
15  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Sinking Current, Vo = 0V  
1.2  
- 40 C  
85 C  
25 C  
1.0  
0.8  
0.6  
0.4  
0.2  
0.0  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 18 - Sinking Current vs. Supply Voltage  
Vos vs. VS  
140.0E-6  
120.0E-6  
100.0E-6  
80.0E-6  
60.0E-6  
40.0E-6  
20.0E-6  
000.0E+0  
85 C  
- 40 C  
25 C  
2.0  
2.5  
3.0  
3.5  
4.0  
4.5  
5.0  
5.5  
6.0  
6.5  
7.0  
+/- Supply (V)  
Figure 19 - Vos vs. VS  
16  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Vos vs Vcm  
7.0E-3  
6.0E-3  
5.0E-3  
4.0E-3  
3.0E-3  
2.0E-3  
85 C  
1.0E- 3  
- 40 C  
25 C  
000.0E+0  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
Vcm (V)  
Figure 20 - Vos vs. Vcm  
Vos vs. Vcm, VS = +/- 2.5V  
600.0E-6  
500.0E-6  
400.0E-6  
300.0E-6  
200.0E-6  
100.0E-6  
000.0E+0  
25 C  
85 C  
-40 C  
0.0  
0.2  
0.4  
0.6  
0.8  
1.0  
1.2  
1.4  
1.6  
Vcm (V)  
Figure 21 - Vos vs. Vcm, Vs = ±2.5V  
17  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Bias Current vs. Vsupply  
-4.0E-6  
-4.5E-6  
-5.0E-6  
-5.5E-6  
- 40 C  
-6.0E-6  
-6.5E-6  
25 C  
-7.0E-6  
-7.5E-6  
85 C  
-8.0E-6  
-8.5E-6  
-9.0E-6  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 22 - Bias Current vs. Vsupply  
Offset Current vs. Vsupply  
25.0E-9  
20.0E-9  
15.0E- 9  
10.0E- 9  
5.0E-9  
85 C  
25 C  
- 40 C  
000.0E+0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
+/- Supply (V)  
Figure 23 - Offset Current vs. Vsupply  
18  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Load  
F = 1MHz, Vout = 2Vpp  
-60  
-65  
-70  
3r d Har monic  
-75  
-80  
-85  
-90  
2nd Har monic  
-95  
-100  
-105  
0
50  
100  
150  
200  
250  
300  
350  
400  
450  
500  
Load Resistance (ohms)  
Figure 24 - Harmonic Distortion vs. Load F = 1MHZ, Vout = 2Vpp  
Harmonic Distortion vs. Load  
VS = +/- 2.5V, F = 1MHz, Vout = 2Vpp  
-60  
-65  
-70  
-75  
3r d Har monic  
2nd Har monic  
-80  
-85  
-90  
-95  
-100  
-105  
0
50  
100  
150  
200  
250  
300  
350  
400  
450  
500  
Load Resistance (ohms)  
Figure 25 - Harmonic Distortion vs. Load Vs = ±2.5V, F = 1MHz, Vout = 2Vpp  
19  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Output Voltage  
VS = +/- 2.5V, F = 1MHz  
-40  
-50  
-60  
3r d Har monic  
-70  
-80  
-90  
2nd Har monic  
-100  
-110  
0.0  
0.5  
1.0  
1.5  
2.0  
2.5  
3.0  
Output Voltage (Vpp)  
Figure 26 - Harmonic Distortion vs. Output Voltage Vs = ±2.5V, F = 1MHz  
Harmonic Distortion vs. Output Voltage  
F = 1MHz  
-40  
-50  
-60  
-70  
3r d Har monic  
-80  
-90  
2nd Har monic  
-100  
-110  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
8.0  
9.0  
10.0  
Output Voltage (Vpp)  
Figure 27 - Harmonic Distortion vs. Output Voltage F = 1MHz  
20  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Output Voltage  
VS = +/- 2.5V, F = 1MHz, RL = 25ohms  
-40  
-50  
3r d Har monic  
-60  
-70  
2nd Har monic  
-80  
-90  
-100  
0.0  
0.5  
1.0  
1.5  
2.0  
2.5  
3.0  
Output Voltage (Vpp)  
Figure 28 - Harmonic Distortion vs. Output Voltage Vs = ±2.5V, F = 1MHz, RL = 25Ω  
Harmonic Distortion vs. Output Voltage  
F = 1MHz, RL = 25ohm s  
-40  
-50  
-60  
-70  
-80  
-90  
-100  
2nd Har monic  
3r d Har monic  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
8.0  
9.0  
10.0  
Output Voltage (Vpp)  
Figure 29 - Harmonic Distortion vs. Output Voltage F = 1MHz, RL = 25Ω  
21  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Output Voltage  
F = 10MHz  
-20  
-30  
3r d Har monic  
-40  
-50  
2nd Har monic  
-60  
-70  
-80  
-90  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
8.0  
9.0  
10.0  
Output Voltage (Vpp)  
Figure 30 - Harmonic Distortion vs. Output Voltage F = 10MHz  
Harmonic Distortion vs. Output Voltage  
F = 10MHz, RL = 25ohm s  
-20  
-30  
-40  
-50  
-60  
-70  
-80  
3r d Har monic  
2nd Har monic  
0.0  
1.0  
2.0  
3.0  
4.0  
5.0  
6.0  
7.0  
8.0  
9.0  
10.0  
Output Voltage (Vpp)  
Figure 31 - Harmonic Distortion vs. Output Voltage F = 10MHz, RL = 25Ω  
22  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Frequency  
Vout = 2Vpp  
-30  
-40  
-50  
-60  
3r d Har monic  
-70  
-80  
2nd Har monic  
-90  
-100  
-110  
-120  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 32 - Harmonic Distortion vs. Frequency Vout = 2Vpp  
Harmonic Distortion vs. Output Voltage  
VS = +/- 2.5V, F=10MHz  
-30  
-40  
-50  
-60  
-70  
-80  
3r d Har monic  
2nd Ha r monic  
-90  
0.0  
0.5  
1.0  
1.5  
2.0  
2.5  
3.0  
Output Voltage (Vpp)  
Figure 33 - Harmonic Distortion vs. Output Voltage Vs = ±2.5V, F = 10MHz  
23  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Frequency  
Vout = 2Vpp, RL = 25ohms  
-30  
-40  
-50  
3r d Har monic  
-60  
-70  
2nd Har monic  
-80  
-90  
-100  
-110  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 34 - Harmonic Distortion vs. Frequency Vout = 2Vpp, RL = 25Ω  
Harmonic Distortion vs. Output Voltage  
VS = +/- 2.5V, F = 10MHz, RL = 25 ohms  
-20  
-30  
-40  
-50  
-60  
-70  
-80  
3 r d Har monic  
2nd Har monic  
0.0  
0.5  
1.0  
1.5  
2.0  
2.5  
3.0  
Output Voltage (Vpp)  
Figure 35 - Harmonic Distortion vs. Output Voltage Vs = ±2.5V, F = 10MHz, RL = 25Ω  
24  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Harmonic Distortion vs. Frequency  
VS = +/- 2.5V, Vout = 2Vpp  
-30  
-40  
-50  
-60  
3r d Har monic  
-70  
-80  
2nd Har monic  
-90  
-100  
-110  
-120  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 36 - Harmonic Distortion vs. Frequency Vs = ±2.5V, Vout = 2Vpp  
Harmonic Distortion vs. Frequency  
VS = +/- 2.5V, Vout = 2Vpp, RL = 25ohms  
-30  
-40  
-50  
-60  
-70  
-80  
-90  
-100  
-110  
3r d Har monic  
2nd Har monic  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 37 - Harmonic Distortion vs. Frequency Vs = ±2.5V, Vout = 2Vpp, RL = 25Ω  
25  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Small Signal Frequency Response  
25.0  
G = 10  
20.0  
15.0  
G = 5  
10.0  
5.0  
G = 2  
0.0  
-5.0  
-10.0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
100.0E+6  
1.0E+9  
Frequency (Hz)  
Figure 38 - Small Signal Frequency Response  
Frequency Response, Vo = 200mVpp  
8.0  
VS = 12V  
6.0  
4.0  
2.0  
VS = 5V  
0.0  
-2.0  
-4.0  
-6.0  
100.0E+3  
1.0E+6  
10.0E+6  
100.0E+6  
1.0E+9  
Frequency (Hz)  
Figure 39 - Frequency Response, VO = 200mVpp  
26  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Pulse Response  
2.5  
2.0  
1.5  
1.0  
0.5  
0.0  
-0.5  
-1.0  
-1.5  
-2.0  
-2.5  
5.4E-6  
5.5E-6  
5.6E-6  
5.7E-6  
5.8E-6  
5.9E-6  
6.0E-6  
6.1E-6  
Time (s)  
Figure 40 - Pulse Response  
Pulse Response, VS = +/- 2.5V  
0.6  
0.4  
0.2  
0.0  
-0.2  
-0.4  
-0.6  
5.4E-6  
5.5E-6  
5.6E-6  
5.7E-6  
5.8E-6  
5.9E-6  
6.0E-6  
6.1E-6  
Time (s)  
Figure 41 - Pulse Response, Vs = ±2.5V  
27  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
PSRR vs. Frequency  
100  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
10.0E+0  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 42 - PSRR vs Frequency  
CMRR vs. Frequency  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
10.0E+0  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 43 - CMRR vs. Frequency  
28  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
PSRR vs. Frequency  
VS = +/- 2.5V  
100  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
10.0E+0  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 44 - PSRR vs. Frequency Vs = ±2.5V  
CMRR vs. Frequency  
VS = +/- 2.5V  
90  
80  
70  
60  
50  
40  
30  
20  
10  
0
10.0E+0  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 45 - CMRR vs. Frequency Vs = ±2.5V  
29  
Zarlink Semiconductor Inc.  
ZL40167  
Data Sheet  
Typical Performance Characteristics At TA = 25°C, RF = RG = 510, gain = +2, RL = 100, Vs = 6V. Unless  
otherwise specified.  
Input Noise Voltage vs. Frequency  
3.85E-09  
3.80E-09  
3.75E-09  
3.70E-09  
VS =+/ - 2. 5V  
3.65E-09  
3.60E-09  
VS =+/ - 6V  
3.55E-09  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 46 - Noise Voltage vs. Frequency  
Input Current Noise vs. Frequency  
4.0E-12  
3.8E-12  
3.6E-12  
3.4E-12  
3.2E-12  
3.0E-12  
2.8E-12  
2.6E-12  
2.4E-12  
2.2E-12  
2.0E-12  
VS=+/-2.5V  
VS=+/-6V  
100.0E+0  
1.0E+3  
10.0E+3  
100.0E+3  
1.0E+6  
10.0E+6  
Frequency (Hz)  
Figure 47 - Current Noise vs. Frequency  
30  
Zarlink Semiconductor Inc.  
For more information about all Zarlink products  
visit our Web Site at  
www.zarlink.com  
Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable.  
However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such  
information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or  
use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual  
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certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink.  
This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part  
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any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user’s responsibility to fully determine the performance and  
suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does  
not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in  
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Purchase of Zarlink’s I2C components conveys a licence under the Philips I2C Patent rights to use these components in and I2C System, provided that the system  
conforms to the I2C Standard Specification as defined by Philips.  
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TECHNICAL DOCUMENTATION - NOT FOR RESALE  

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