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PBL385411SO-T 参数 Datasheet PDF下载

PBL385411SO-T图片预览
型号: PBL385411SO-T
PDF下载: 下载PDF文件 查看货源
内容描述: 环球巡回演讲 [Universal Speech Circuit]
分类和应用:
文件页数/大小: 14 页 / 280 K
品牌: ERICSSON [ ERICSSON ]
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PBL 385 41  
PBL 385 41  
4
PBL 385 41  
(b)  
(a)  
DC  
11  
12  
11  
12  
( ref. 1.2V )  
PBL  
385 41  
constant  
current  
generator  
M
M
13  
13  
+
+
Dynamic  
microphone  
Unbalanced electret  
mic. with balanced  
signal, DC-supply from  
pin 4.  
ref. minus  
a diode 0.5V  
11  
DC  
R
Pin 8 or9.  
(d)  
4
PBL 385 41  
(c)  
PBL 385 41  
DC-  
load  
AC-  
load  
11  
11  
12  
12  
M
M
13  
13  
+
+
C
+
Balanced electret  
microphone  
DC-load = R4+R5  
AC-load = R4+R5//ZTI  
Balanced electret microphone.  
An additional RC filterlink is  
recommended if pin 4 is used  
as a supply.  
Figure 10. Microphone solutions.  
Figure 9. Microphone amplifier output clipping.  
Transmitter amplifier  
The transmitter amplifier in PBL38541 consists of three stages. The first stage is an amplitude limiter for the input signal at TI, in  
order to prevent the transmitted signal to exceed a certain set level and cause distortion. The second stage amplifies further the signal  
fromthefirstandaddsittoaDClevelfromaninternalDC-regulationloop inordertogive therequiredDCcharacteristictothetelephone  
set. The output of this stage is TO. The third stage is a current generator that presents a high impedance towards the line and has its  
gain from TO to +L. The gain of this amplifier is ZL/R6 where ZL is the impedance across the telephone line. Hence, the absolute  
maximum signal amplitude that can be transmitted to the line undistorted is dependent of R6. (amplitude limiting)  
The transmitter gain and frequency response are set by the RC-network between the pins 11 and 3. See fig.11. The capacitor  
for cutting the high end of frequency band is best to be placed directly at the microphone where it also will act as a RFI suppressor.  
The input signal source impedance to the transmitter amplifier input TI should be reasonably low in order to keep the gain spread down,  
saying that R4//R5 (see fig. 4) must be at least a factor 5 lower than the ZTin. Observe that the capacitor C1 should have a reasonably  
good temperature behaviour in order to keep the impedance rather constant. The V+C´s influence on the transmitter DC-characteristic  
is shown in the fig.8 (DC-characteristic), therefore the transmitter gain would change if the transmitted signal gives reason to an ac-  
voltage leak signal across C1 since this is a feedback point. If the transmitter has an unacceptable low sving to the line at low line  
currents <10mA the first step should be to examine if the circuits DC characteristic can be adjusted upwards.  
How to calculate the gains in the transmitter channel.  
See fig. 2 and 4.  
Microphone amplifiers first stage 19 dB.  
Microphone amplifiers regulated second stage 10.5 dB - 15.5 dB  
Regulation interval 10.5 - 15.5 dB  
low gain 19.0 + 10.5 dB = 29.5 dB  
high gain 19.0 + 15.5 dB = 34.5 dB  
V
V
2
3
R
M
R
5
R
TX  
load  
=
G
M
G
Z
mic +R  
M
R
4
+R  
5
R
6
RM = Microphone amplifier input resistance  
= R // R  
R
load  
line  
telephone  
ex. calculate the gain of the transmitter stage GTX at 0 - line length:  
(1. 7 / /2. 7)k  
(17 / /22)k  
18k + (17 / /22)k  
600/ /910Ω  
75Ω  
43 = 20log(  
) + 29.5 + 20log(  
) + GTX + 20log(  
)
350Ω + (1. 7 / /2. 7)k  
43 = −2.51+ 29.5 9.17 + GTX +13.66  
TX = 11.52dB  
G
7