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摘要:本应用笔记介绍了压控振荡器(VCO)的槽路设计方法,并给出了常用的中频(IF) 85MHz、190MHz、210MHz压控振荡器的设计实例。这些设计减少了为优化设计而进行的重复工作,具体分析可借助一个简单的电子表格实现。
更多信息:
概述
本应用笔记介绍了压控振荡器(VCO)的槽路设计方法,并给出了常用的中频(IF) 85MHz、190MHz、210MHz压控振荡器的设计实例。这些设计减少了为优化设计而进行的重复工作,具体分析可借助一个简单的电子表格实现。
VCO设计
图2表示MAX2310 IF VCO的差分槽路,为便于分析,所给槽路只是一个简单的等效模型。图1表示基本的VCO模型,振荡频率由式1表示:
|
式1
|
fosc = 振荡频率
L = 槽路线圈的电感值
Cint = MAX2310槽路端口的内部电容
Ct = 槽路的总计等效电容
图1. 基本的VCO模型
Rn = MAX2310槽路端口的等效负阻
Cint = MAX2310槽路端口的内部电容
Ct = 槽路的总计等效电容
L = 槽路线圈的电感值
图2. MAX2310槽路
电感L与槽路等效电容和振荡器内部电容的总和产生谐振(Ct+Cint) (参见图1)。Ccoup提供隔直流、并将变容二极管的可变电容耦合至槽路。Ccent用来确定槽路振荡频率标称值的中心。它不是必须的,但为在不同的电感量之间调谐谐振腔提供了便利条件。电阻(R)通过调谐电压(Vtune)为变容二极管提供相反的偏置。应选择足够大的阻值,以保证加载后的槽路Q值不受影响;另外,还要保证电阻值足够小,使4kTBR噪声可以忽略。电阻的噪声电压受KVCO调制后将产生相位噪声。电容Cv是槽路内部的可变调谐元件,变容二极管的电容(Cv)是反向偏置电压的函数(变容二极管模型参见附录A)。Vtune是来自锁相环(PLL)的调谐电压。
图3在VCO模型中增加了Cstray,寄生电容和寄生电感使所有射频(RF)电路的罪魁祸首,为估算振荡频率必须考虑寄生参数。图3用电容Cstray表示寄生元件,振荡频率可由式2表示:
|
式2
|
L = 槽路线圈的电感值
Cint = MAX2310槽路端口的内部电容
Ccent = 用于确定中心振荡频率的槽路电容
Cstray = 电容漂移
Ccoup = 槽路电容,用来将变容二极管耦合至槽路
Cv = 变容二极管电容的净变量(包括串联电感)
Cvp = 变容二极管焊盘的电容
图3. Cstray模型
图4表示VCO模型的详细电路,它考虑了焊盘的等效电容,但为简便起见没有考虑串联电感。Cstray定义为:
 |
式3
|
CL = 电感的电容量
CLP = 电感焊盘的电容量
CDIFF = 平行引线的等效电容
图4. 详细的VCO模型
Rn = MAX2310槽路端口的等效负阻
Cint = MAX2310槽路端口的内部电容
LT = 电感槽路引线的串联电感
CDIFF = 平行引线的等效电容
L = 槽路线圈电感
CL = 电感等效电容
CLP = 电感焊盘等效电容
Ccent = 用于确定中心振荡频率的槽路电容
Ccoup = 槽路电容,用来将变容二极管耦合至槽路
Cvar = 变容二极管电容的变化量
Cvp = 变容二极管焊盘电容
LS = 变容二极管串联电感
R = 变容二极管反向偏置电阻的阻值
为简化分析,设计中忽略了电感LT。LT通常对高频端影响较大,为了用下面的电子表格描述LT所产生的频率偏差的数学模型,可适当增大CDIFF,减小LT以避免产生所不希望的串联谐振。这一点可通过缩短引线实现。
调谐增益
为获得最佳的闭环相位噪声特性应尽可能降低调谐增益(Kvco),环路滤波器的电阻和电阻“R” (图2)会产生宽带噪声,宽带热噪声( )将按照Kvco调制VCO输出,用单位MHz/V表示。减小Kvco的途径有两条:一是降低压控振荡器的调谐范围;第二种方法是增大所允许的调节电压范围。要在保证足够的VCO调谐频率范围的前提下减小其调谐范围,需要选用容差极小的元器件,后面将对这一点作详细描述。为扩大电压调节范围,需采用电荷泵电路以提供适当的电压范围,这种方式一般需要采用更高的Vcc。MAX2310允许的电压调节范围是:0.5V至Vcc-0.5V。电池供电应用中,电压调节范围受电池电压或稳压器的制约。
免调节设计的基本概念
VCO槽路设计中需对实际部件进行误差分析,为了设计一个振荡在固定频率(fosc)的VCO,必须考虑元件误差。在设计调谐增益(Kvco)时必须将这些元件容差考虑进去。元件容差越小、可能产生的调谐增益越小,闭环相位噪声就越低。考虑误差最大的情况,可以用以下三种VCO模型表示:
- 元件最大值(式5)
- 标准谐振电路,对应于元件标称值(式2)
- 元件最小值(式4)
三种VCO模型都必须覆盖所期望的标称频率,图5描述了如何将三种设计统一起来,以便提供可行的设计方案。从式1和图5可以看出:元件最小值对应于振荡频率的高频端偏移,而元件最大值对应于振荡频率的低频端偏移。
图5. 极端情况下的槽路中心频率和标称中心频率
为保证槽路的闭环相位噪声最小,需尽可能减小调谐范围。但要注意在考虑系统最大容差时仍能覆盖标准振荡频率。元件值分别达到最大和最小时,槽路的调谐范围尽量靠近所期望的振荡频率的边沿,考虑到系统容差对式2加以修正,可得最大误差时对应的振荡频率式4、式5:
|
式4
|
 |
式5
|
TL = %电感(L)的容差
TCINT = %电容(CINT)的容差
TCCENT = %电容(CCENT)的容差
TCCOUP = %电容(CCOUP)的容差
TCV = %变容二极管电容(CV)的容差
式4和式5假设偏差量没有容差。
一般设计过程
步骤1
估算或测量焊点的寄生电容或其它寄生电容:用Boonton 72BD电容计对MAX2310评估板(Rev C)进行测试,测得寄生电容为:CLP
= 1.13pF、CVP = 0.82pF、CDIFF = 0.036pF。
步骤2
确定电容Cint:这个参数在MAX2310/MAX2312/MAX2314/MAX2316数据资料的第5页查找到,谐振端口的1/S11随频率变化的典型工作特性给出了几个常用频点时的等效并联RC参数,附录B包含了槽路端口频率在高频端和低频端时Cint与频率的对应关系表。需要牢记的是本振频率为IF频率的两倍。
例如:
如果IF为210MHz (高频端谐振电路),本振工作频率应为420MHz。由附录B的表5可得Cint = 0.959pF。
步骤3
选择电感:最好从几何平均值入手,这是一个需要重复迭代的过程。
 |
式6
|
上式中电感、电容的单位分别用nH、pF表示(1x10-9 x 1x10-12 = 1x10-21)。 如果fosc = 420MHz、L = 11.98nH,则槽路总计电容为C = 11.98pF。最初选择容差为2%、电感量为12nH的Coilcraft 0805CS-12NXGBC比较恰当。
如果选择电感具有一定的局限性时,式6.1将是一个很有用的公式。对于一个固定振荡频率fosc,LC的乘积应保持恒定。
|
式6.1
|
fosc = 420MHz时,LC = 143.5,按照表3采用试凑的方法可以得到:电感取18nH、容差为2%,而槽路总电容为7.9221pF。此时,图8中LC乘积为142.59,非常接近理论值143.5。由此可以看出上述关系时的实用性。为保证较低的相位噪声,选用高Q值电感,如:Coilcraft 0805CS系列,如果能够合理控制微带线的容差和Q值,也可选用微带线。
步骤4
确定锁相环(PLL)的合理范围:该参数表示VCO整个调谐电压(Vtune)的工作范围,对于MAX2310,适当范围为:0.5V至Vcc-0.5V,如果Vcc = 2.7V,则调谐电压范围为:0.5V至2.2V,电荷泵输出限定这一范围。槽路电压摆幅为1Vp-p、电压摆幅的中点为1.6V直流,即使选用较大的Ccoup,变容二极管也不会产生正偏。这是一个需要避免的情况,因为二极管将会影响槽路引脚上的交流信号,产生所不期望的杂散响应、造成闭环PLL的失锁。
步骤5
选择变容二极管,在所规定的调谐电压范围内选择容差较小的变容二极管,并保证串联电阻最小,确认变容二极管的自共振频率高于所期望的工作频率。在规定的工作电压范围内察看Cv(2.5V)/Cv(0.5V)的比率。如果选择较大的耦合电容Ccoup,最大调谐范围可利用式2计算;如果选择较小的耦合电容Ccoup,将会降低有效的频率调谐范围。选择变容二极管时需给出调谐范围的中点和端点处的容差,可以选择一个特性曲线较陡峭的变容二极管,如Alpha SMV1763-079,进行线性调节。取槽路总电容、并将其用于变容二极管的Cjo。注意,Ccoup会降低变容二极管耦合到槽路的电容。
步骤6
确定耦合电容Ccoup:Ccoup较大时,变容二极管耦合到槽路的电容较大、使调谐范围增大,但会降低槽路加载后的Q值。Ccoup较小时,会提高耦合变容二极管的Q值和加载后的Q值,但它是以减小调谐范围为代价的。通常是在保证调谐范围的前提下尽可能选择小的容量值。选择较小Ccoup的另一个好处是可以降低变容二极管两端的电压摆幅。
步骤7
确定电容Ccent。一般Ccent取2pF,考虑到电容误差也可选用稍微大一点的电容。利用Ccent调整VCO的标准频率。
步骤8
按照制作的电子表格推敲设计参数。
MAX2310在85MHz、190MHz和210MHz IF时的VCO槽路设计
下列电子表格给出了MAX2310在几个通用IF频点的设计,请牢记:LO振荡频率应为所期望的IF频率的两倍。
图6. 85MHz低频端IF槽路
表1. 85MHz低频端IF槽路设计
| |
Light grey indicates calculated values. |
| |
Darker grey indicates user input. |
| MAX2310 Low-Band Tank Design and Tuning Range |
| Total Tank Capacitance vs. V tune |
| V tune
|
Total
C |
Ct
(Nominal) |
Ct
(Low) |
Ct
(High) |
| 0.5V |
Ct
high |
14.1766pF |
13.3590pF |
14.9459pF |
| 1.375V |
Ct
mid |
12.8267pF |
11.7445pF |
13.7620pF |
| 2.2V |
Ct
low |
11.4646pF |
10.3049pF |
12.4534pF |
| |
| Tank Components |
Tolerance
|
|
C coup
|
18pF
|
0.9pF
|
5%
|
|
C cent
|
5.6pF
|
0.1pF
|
2%
|
|
C stray
|
0.70pF
|
|
|
|
L
|
68nH
|
2.00%
|
|
|
C int
|
0.902pF
|
10.00%
|
|
| |
| Parasitics
and Pads (C stray) |
| Due to
Q |
C L
|
0.1pF
|
| Ind. pad |
C Lp
|
1.13pF
|
| Due to
|| |
C diff
|
0.036pF
|
| Var. pad |
C vp
|
0.82pF
|
| |
| Varactor
Specs |
| Alpha
SMV1255-003 |
| Cjo |
82pF
|
Varactor Tolerance
|
| Vj |
17V
|
0.5V
|
19.00%
|
| M |
14
|
1.5V
|
29.00%
|
| Cp |
0pF
|
2.5V
|
35.00%
|
| Rs |
1Ω
|
Reactance
|
| Ls |
1.7nH
|
X Ls
|
1.82 |
| Freq |
170.00MHz
|
|
| |
| Nominal Varactor |
X c
|
Net Cap
|
|
Cv high
|
54.64697pF
|
-17.1319
|
61.12581pF
|
|
Cv mid
|
27.60043pF
|
-33.92
|
29.16154pF
|
|
Cv low
|
14.92387pF
|
-62.7321
|
15.36874pF
|
| |
| Negative Tol Varactor (Low Capacitance) |
|
Cv high
|
44.26404pF
|
-21.1505
|
48.42117pF
|
|
Cv mid
|
19.59631pF
|
-47.7746
|
20.37056pF
|
|
Cv low
|
9.700518pF
|
-96.5109
|
9.886531pF
|
| |
| Positive Tol Varactor (High Capacitance) |
|
Cv high
|
65.02989pF
|
-14.3965
|
74.41601pF
|
|
Cv mid
|
35.60456pF
|
-26.2945
|
38.24572pF
|
|
Cv low
|
20.14723pF
|
-46.4682
|
20.96654pF
|
| |
| |
Nominal
LO
(Nom) Range |
Low
Tol IF
(High) Range |
Nominal
IF
(Nom) Range |
High
Tol IF
(Low) Range |
|
F low
|
162.10MHz
|
84.34MHz
|
81.05MHz
|
78.16MHz
|
|
F mid
|
170.42MHz
|
89.95MHz
|
85.21MHz
|
81.45MHz
|
|
F high
|
180.25MHz
|
96.03MHz
|
90.13MHz
|
85.62MHz
|
|
BW
|
18.16MHz
|
11.69MHz
|
9.08MHz
|
7.46MHz
|
|
% BW
|
10.65%
|
12.99%
|
10.65%
|
9.16%
|
| |
| Nominal
IF Frequency |
85.00MHz
|
| |
|
Design
Constraints
|
| Condition for
bold number |
<IF
|
=IF
|
> IF
|
| Delta |
0.66
|
-0.21
|
0.62
|
| Test |
pass
|
pass
|
pass
|
| Raise
or lower cent freq by |
-0.21
|
MHz
|
| Inc or
dec BW |
-1.28
|
MHz
|
| Cent
adj for min BW |
84.98
|
MHz
|
| |
| K vco |
10.68MHz/V
|
图7. 190MHz高频端IF槽路
表2. 190MHz高频端IF槽路设计
| |
Light grey indicates calculated values. |
| |
Darker grey indicates user input. |
| MAX2310 High-Band Tank Design and Tuning Range |
| Total Tank Capacitance vs. V tune |
|
V tune
|
Total
C |
Ct
(Nominal) |
Ct
(Low) |
Ct
(High) |
|
0.5V
|
Ct
high |
10.4968pF |
10.0249pF |
10.9126pF |
|
1.375V
|
Ct
mid |
9.6292pF |
8.8913pF |
10.2124pF |
|
2.2V
|
Ct
low |
8.6762pF |
7.7872pF |
9.3717pF |
| |
| Tank
Components |
Tolerance
|
|
C coup
|
12pF
|
0.1pF
|
1%
|
|
C cent
|
3.4pF
|
0.1pF
|
3%
|
|
C stray
|
0.70pF
|
|
|
|
L
|
18nH
|
2.00%
|
|
|
C int
|
0.954pF
|
10.00%
|
|
| |
| Parasitics
and Pads (C stray) |
| Due to Q |
C L
|
0.01pF
|
| Ind. pad |
C Lp
|
1.13pF
|
| Due to || |
C diff
|
0.036pF
|
| Var. pad |
C vp
|
0.82pF
|
| |
| Varactor
Specs |
| Alpha
SMV1255-003 |
| Cjo |
82pF
|
Varactor Tolerance
|
| Vj |
17V
|
0.5V
|
19.00%
|
| M |
14
|
1.5V
|
29.00%
|
| Cp |
0pF
|
2.5V
|
35.00%
|
| Rs |
1Ω
|
Reactance
|
| Ls |
1.7nH
|
X Ls
|
4.06 |
| Freq |
380.00MHz
|
|
| |
| Nominal
Varactor |
X c
|
Net Cap
|
|
Cv high
|
54.64697pF
|
-7.66426
|
116.1695pF
|
|
Cv mid
|
27.60043pF
|
-15.1747
|
37.67876pF
|
|
Cv low
|
14.92387pF
|
-28.0643
|
17.44727pF
|
| |
| Negative
Tol Varactor (Low Capacitance) |
|
Cv high
|
44.26404pF
|
-9.46205
|
77.51615pF
|
|
Cv mid
|
19.59631pF
|
-21.3728
|
24.19031pF
|
|
Cv low
|
9.700518pF
|
-43.1759
|
10.70708pF
|
| |
| Positive Tol Varactor (High Capacitance) |
|
Cv high
|
65.02989pF
|
-6.44056
|
175.8588pF
|
|
Cv mid
|
35.60456pF
|
-11.7633
|
54.36221pF
|
|
Cv low
|
20.14723pF
|
-20.7884
|
25.03539pF
|
| |
| |
Nominal LO
(Nom) Range |
Low Tol IF
(High) Range |
Nominal IF
(Nom) Range |
High Tol IF
(Low) Range |
|
F low
|
366.15MHz
|
189.23MHz
|
183.07MHz
|
177.78MHz
|
|
F mid
|
382.29MHz
|
200.94MHz
|
191.14MHz
|
183.78MHz
|
|
F high
|
402.74MHz
|
214.71MHz
|
201.37MHz
|
191.84MHz
|
|
BW
|
36.59MHz
|
25.47MHz
|
18.29MHz
|
14.06MHz
|
|
% BW
|
9.57%
|
12.68%
|
9.57%
|
7.65%
|
| |
| Nominal
IF Frequency |
190MHz
|
| |
|
Design
Constraints
|
| Condition for
bold number |
< IF
|
= IF
|
> IF
|
| Delta |
0.77
|
-1.14
|
1.84
|
| Test |
pass
|
pass
|
pass
|
| Raise or lower cent freq
by |
-1.14
|
MHz
|
| Inc or dec BW |
-2.61
|
MHz
|
| Cent adj for min BW |
190.54
|
MHz
|
| |
| K vco |
21.52MHz/V
|
图8. 210MHz高频端IF槽路
表3. 210MHz高频端IF槽路设计
| |
Light grey indicates calculated values. |
| |
Darker grey indicates user input. |
| MAX2310 High-Band Tank Design and Tuning Range |
| Total Tank Capacitance vs. V tune |
|
V tune
|
Total C |
Ct
(Nominal) |
Ct
(Low) |
Ct (High) |
|
0.5V
|
Ct high |
8.8304pF |
8.1465pF |
9.4877pF |
|
1.35V
|
Ct mid |
7.9221pF |
7.0421pF |
8.6970pF |
|
2.2V
|
Ct low |
6.9334pF |
5.9607pF |
7.7653pF |
| |
| Tank Components |
Tolerance
|
|
C coup
|
12pF
|
0.6pF
|
5%
|
|
C cent
|
1.6pF
|
0.1pF
|
6%
|
|
C stray
|
0.70pF
|
|
|
|
L
|
18nH
|
2.00%
|
|
|
C int
|
0.959pF
|
10.00%
|
|
| |
| Parasitics and Pads (C stray) |
| Due to Q |
C L
|
0.1pF
|
| Ind. pad |
C Lp
|
1.13pF
|
| Due to || |
C diff
|
0.036pF
|
| Var. pad |
C vp
|
0.82pF
|
| |
| Varactor Specs |
| Alpha SMV1255-003 |
| Cjo |
82pF
|
Varactor Tolerance
|
| Vj |
17V
|
0.5V
|
19.00%
|
| M |
14
|
1.5V
|
29.00%
|
| Cp |
0pF
|
2.5V
|
35.00%
|
| Rs |
1Ω
|
Reactance
|
| Ls |
1.7nH
|
X Ls
|
4.49 |
| Freq |
420.00MHz
|
|
| |
| Nominal
Varactor |
X
c
|
Net
Cap
|
|
Cv high
|
54.64697pF
|
-6.93433
|
154.787pF
|
|
Cv mid
|
27.60043pF
|
-13.7295
|
40.99616pF
|
|
Cv low
|
14.92387pF
|
-25.3916
|
18.12647pF
|
| |
| Negative
Tol Varactor (Low Capacitance) |
|
Cv high
|
44.26404pF
|
-8.56091
|
92.99806pF
|
|
Cv mid
|
19.59631pF
|
-19.3373
|
25.51591pF
|
|
Cv low
|
9.700518pF
|
-39.0639
|
10.95908pF
|
| |
| Positive
Tol Varactor (High Capacitance) |
|
Cv high
|
65.02989pF
|
-5.82717
|
282.5852pF
|
|
Cv mid
|
35.60456pF
|
-10.643
|
61.54791pF
|
|
Cv low
|
20.14723pF
|
-18.8086
|
26.45795pF
|
| |
| |
Nominal LO
(Nom) Range |
Low Tol IF
(High) Range |
Nominal IF
(Nom) Range |
High Tol IF
(Low) Range |
|
F low
|
399.20MHz
|
209.92MHz
|
199.60MHz
|
190.67MHz
|
|
F mid
|
421.47MHz
|
225.78MHz
|
210.73MHz
|
199.14MHz
|
|
F high
|
450.52MHz
|
245.41MHz
|
225.26MHz
|
210.75MHz
|
|
BW
|
51.31MHz
|
35.49MHz
|
25.66MHz
|
20.09MHz
|
|
% BW
|
12.18%
|
15.72%
|
12.18%
|
10.09%
|
| |
| Nominal IF Frequency |
210MHz
|
| |
|
Design
Constraints
|
| condition for bold number |
< IF
|
= IF
|
> IF
|
| Delta |
0.08
|
-0.73
|
0.75
|
| Test |
pass
|
pass
|
pass
|
| Raise or lower cent freq by |
-0.73
|
MHz
|
| Inc or dec BW |
-0.83
|
MHz
|
| Cent adj for min BW |
210.34
|
MHz
|
| |
| K vco |
30.18MHz/V
|
图9. 高-Q值210MHz高频端IF槽路
表4. 高-Q值210MHz高频端IF槽路设计
| |
Light grey indicates calculated values. |
| |
Darker grey indicates user input. |
| MAX2310 High-Band Tank Design and Tuning Range |
| Total Tank Capacitance vs. V tune |
|
V tune
|
Total C |
Ct
(Nominal) |
Ct
(Low) |
Ct (High) |
|
0.5V
|
Ct high |
5.8856 |
5.5289 |
6.2425 |
|
1.375V
|
Ct mid |
5.2487 |
4.9113 |
5.5858 |
|
2.2V
|
Ct low |
4.8371 |
4.5156 |
5.1581 |
| |
| Tank Components
|
|
C coup
|
15pF
|
0.75pF
|
5%
|
|
C cent
|
1.6pF
|
0.1pF
|
6%
|
|
C stray
|
0.77pF
|
|
|
|
L
|
27
|
2.00%
|
|
|
C int
|
0.959
|
10.00%
|
|
| |
| Parasitics
and Pads (C stray) |
| Due to Q |
C L
|
0.17pF
|
| Ind. pad |
C Lp
|
1.13pF
|
| Due to || |
C diff
|
0.036pF
|
| Var. pad |
C vp
|
0.82pF
|
| |
| Varactor Specs |
| Alpha SMV1763-079 |
| Cjo |
8.2pF
|
Varactor Tolerance
|
| Vj |
15V
|
0.5V
|
7.50%
|
| M |
9.5
|
1.5V
|
9.50%
|
| Cp |
0.67pF
|
2.5V
|
11.50%
|
| Rs |
0.5Ω
|
Reactance
|
| Ls |
0.8nH
|
X Ls
|
2.11 |
| Freq |
420.00MHz
|
|
| |
| Nominal
Varactor |
X
c
|
Net
Cap
|
|
Cv high
|
6.67523pF
|
-56.7681
|
6.933064pF
|
|
Cv mid
|
4.23417pF
|
-89.4958
|
4.336464pF
|
|
Cv low
|
2.904398pF
|
-130.471
|
2.952167pF
|
| |
| Negative
Tol Varactor (Low Capacitance) |
|
Cv high
|
6.174588pF
|
-61.3709
|
6.39456pF
|
|
Cv mid
|
3.831924pF
|
-98.8904
|
3.915514pF
|
|
Cv low
|
2.570392pF
|
-147.425
|
2.607736pF
|
| |
| Positive
Tol Varactor (High Capacitance) |
|
Cv high
|
7.175873pF
|
-52.8076
|
7.474698pF
|
|
Cv mid
|
4.636416pF
|
-81.7313
|
4.759352pF
|
|
Cv low
|
3.238404pF
|
-117.015
|
3.297904pF
|
| |
| |
Nominal LO
(Nom) Range |
Low Tol IF
(High) Range |
Nominal IF
(Nom) Range |
High Tol IF
(Low) Range |
|
F low
|
399.25MHz
|
208.05MHz
|
199.62MHz
|
191.92MHz
|
|
F mid
|
422.78MHz
|
220.75MHz
|
211.39MHz
|
202.89MHz
|
|
F high
|
440.40MHz
|
230.22MHz
|
220.20MHz
|
211.14MHz
|
|
BW
|
41.15MHz
|
22.16MHz
|
20.58MHz
|
19.21MHz
|
|
% BW
|
9.73%
|
10.04%
|
9.73%
|
9.47%
|
| |
| Nominal IF Frequency |
210MHz
|
| |
|
Design
Constraints
|
| Condition for bold number |
< IF
|
= IF
|
> IF
|
| Delta |
1.95
|
-1.39
|
1.14
|
| Test |
pass
|
pass
|
pass
|
| Raise or lower cent freq by |
-1.39
|
MHz
|
| Inc or dec BW |
-3.08
|
MHz
|
| Cent adj for min BW |
209.60
|
MHz
|
| |
| K vco |
24.21MHz/V
|
附录A
图10. 变容二极管模型
Alpha应用笔记AN1004对变容二极管模型提供了更多信息。变容二极管电容定义为式7:
|
式7
|
| Alpha SMV1255-003 |
Alpha SMV1763-079 |
| Cjo = 82 pF |
Cjo = 8.2 pF |
| Vj =17 V |
Vj =15 V |
| M = 14 |
M = 9.5 |
| Cp = 0 |
Cp = 0.67 |
| Rs = 1Ω |
Rs = 0.5Ω |
| Ls = 1.7 nH |
Ls = 0.8 nH |
变容二极管串联电感可以用反向输出的感抗表示,计算新的等效电容Cv为:
|
式8
|
附录B
表5. MAX2310高频槽路中Cint与频率的对应关系
| Frequency (MHz) |
Cint (pF) |
Frequency (MHz) (cont.) |
Cint (pF) (cont.) |
|
100
|
0.708
|
360
|
0.949
|
|
110
|
0.759
|
370
|
0.955
|
|
120
|
0.800
|
380
|
0.954
|
|
130
|
0.809
|
390
|
0.954
|
|
140
|
0.839
|
400
|
0.954
|
|
150
|
0.822
|
410
|
0.955
|
|
160
|
0.860
|
420
|
0.959
|
|
170
|
0.869
|
430
|
0.956
|
|
180
|
0.880
|
440
|
0.959
|
|
190
|
0.905
|
450
|
0.964
|
|
200
|
0.917
|
460
|
0.962
|
|
210
|
0.920
|
470
|
0.963
|
|
220
|
0.926
|
480
|
0.963
|
|
230
|
0.924
|
490
|
0.960
|
|
240
|
0.928
|
500
|
0.964
|
|
250
|
0.935
|
510
|
0.965
|
|
260
|
0.932
|
520
|
0.968
|
|
270
|
0.931
|
530
|
0.966
|
|
280
|
0.933
|
540
|
0.968
|
|
290
|
0.927
|
550
|
0.967
|
|
300
|
0.930
|
560
|
0.974
|
|
310
|
0.933
|
570
|
0.977
|
|
320
|
0.943
|
580
|
0.976
|
|
330
|
0.944
|
590
|
0.984
|
|
340
|
0.945
|
600
|
0.982
|
|
350
|
0.956
|
-
|
-
|
图11. MAX2310高频端槽路中Cint与频率的对应关系(6阶多项式曲线拟和)
表6. MAX2310低频端槽路中Cint与频率的对应关系
| Frequency (MHz) |
Cint (pF) |
Frequency (MHz) (cont.) |
Cint (pF) (cont.) |
|
100
|
0.550
|
360
|
1.001
|
|
110
|
0.649
|
370
|
0.982
|
|
120
|
0.701
|
380
|
0.992
|
|
130
|
0.764
|
390
|
1.001
|
|
140
|
0.762
|
400
|
0.985
|
|
150
|
0.851
|
410
|
0.980
|
|
160
|
0.838
|
420
|
0.986
|
|
170
|
0.902
|
430
|
0.992
|
|
180
|
0.876
|
440
|
0.994
|
|
190
|
0.907
|
450
|
1.001
|
|
200
|
0.913
|
460
|
1.003
|
|
210
|
0.919
|
470
|
1.007
|
|
220
|
0.945
|
480
|
0.992
|
|
230
|
0.952
|
490
|
1.010
|
|
240
|
0.965
|
500
|
1.004
|
|
250
|
0.951
|
510
|
1.011
|
|
260
|
0.954
|
520
|
1.022
|
|
270
|
0.974
|
530
|
1.019
|
|
280
|
0.980
|
540
|
1.044
|
|
290
|
0.973
|
550
|
1.026
|
|
300
|
0.982
|
560
|
1.041
|
|
310
|
0.970
|
570
|
1.038
|
|
320
|
0.982
|
580
|
1.032
|
|
330
|
0.991
|
590
|
1.036
|
|
340
|
0.993
|
600
|
1.025
|
|
350
|
0.991
|
-
|
-
|
图12. MAX2310低频端槽路中Cint与频率的对应关系(6阶多项式曲线拟和)
参考资料
- Chris O'Connor, Develop Trimless Voltage-Controlled Oscillators, Microwaves and RF, July1999.
- Wes Hayward, Radio Frequency Design, Chapter 7.
- Krauss, Bostian, Raab, Solid State Radio Engineering, Chapters 2, 3, 5.
- Alpha Industries Application Note AN1004.
- Coilcraft, RF Inductors Catalog, March 1998, p.131.
- Maxim, MAX2310/MAX2312/MAX2314/MAX2316 Data Sheet, Rev 0.
- Maxim, MAX2310/MAX2314 Evaluation Kit Data Sheet, Rev 0.
- Maxim, MAX2312/MAX2316 Evaluation Kit Data Sheet, Rev 0.
| 相关型号 | |
APP 530: Jul 29, 2003
|
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