Blackjack Average Hands Per Hour
- Blackjack Average Hands Per Hour Table
- Blackjack Average Hands Per Hour Poker
- Blackjack Average Hands Per Hour Zone Poker
Blackjack players at a full table are dealt 60 hands per hour. Assume $10 average bet this means in one hour the person stands to lose $3 due to the house edge ($10 average bet times 60 hands per hour times 0.5% house advantage =$3). Lets assume you are dealt 100 hands per hour, so over the course of two hours you played 200 hands of blackjack. Getting a blackjack once every 21 hands means that you should theoretically have gotten about 10 blackjacks. Sometimes youll get more blackjacks in two hours of play, sometimes less, but on average youll get 10. These cards were divided between the dealer, the other player and me so we each got 234/3 = 78 cards. Each hand I play consists of 2.7 cards on average so in that shoe I played 78/2.7 = 28.88 or approximately 29 rounds. I then do this for all shoes played and add them up and divide by the number of hours played to get rounds per hour.
Chapter 1
Dec 08, 2016 This is also how I got my estimates for the DD game (per my post above). I noted a shuffle about every 5 minutes, 12 per hour. So I multiplied 12 times the theoretical number of hands per shuffle based on number of players and penetration. Dec 08, 2016 We’ll assume that you average 80 hands per hour (a typical number). You’ll see more hands per hour when there are no other players at the table with you, but you’ll also see fewer hands per hour when there are other players at the table. It will take you 50 hours of play per month to get 4000 bets down.
Win Rates
This book contains numerous win rates. Their purpose is to aid in understanding the importance of various rules options. This book assumes that decisions are made on the basis of expected value, also called expected win. Whether an action turns out to have been correct or incorrect on one isolated hand does not matter. What does matter is what the average outcome would be over thousands and thousands of such decisions.
A positive expected win rate means that you are expected to win in the long run, and a negative expected win rate means that you will lose in the long run. For example, when your expected win rate is -0.5%, you are expected to lose at the rate of 0.5%. Here is a question from a reader. I like it because the answer to it is a good example of what this book is all about.
Why should I not split 10-10 when the dealer shows 5?
I like the idea of starting two new hands with a single good card. I am likely to draw totals much better than the dealer will get when he starts with the worst of cards. This reader is correct in that starting with a 10 is likely to lead to a good hand. You will make money if you split 10-10 against the dealer’s 2, 3, 4, 5, 6, 7, 8, or 9. You will make money splitting 10-10 against 10 or ace if you lose only one bet to a natural.
You will also make money if you do not split 10-10. You should split or not split depending on which alternative makes more money. With 10-10 against 5 you make about 25% per hand by splitting but you can make 67% by not splitting. Making 67% is more attractive than twice making 25%. Therefore, basic strategy says do not split 10-10 against 5.
Benchmark Rules
I have selected a benchmark, an arbitrary set of rules, playing conditions, and bets. Use of a different benchmark would result in different numbers. However, the relative importance of different rules variations would be approximately the same no matter what set of rules was used as the benchmark. The benchmark betting scheme is not the best way to bet.
Much better is to leave the table on negative counts. On positive counts, you must bet in a manner that does not attract unwanted attention to yourself. Simulating the base set of rules and betting scheme finds a win rate that is a benchmark for evaluating the cost or benefit of various deviations from the benchmark rules.
Benchmark Rules Six decks.
One-deck cut, meaning five decks are dealt out. Dealer stands on soft seventeen. Double down is allowed on any first two cards but not after splitting. Resplits are allowed to a total of four hands. Split aces receive one card each, and cannot be resplit. Insurance is offered, but no other side bets. No surrender. Naturals pay 3:2, and tie a natural by the dealer. The high-low counting system is used, with strategy numbers from -10 to +10. There is a total of two players at the table. The bet scheme is $100 at counts per deck of +4 or more, $75 at +3, $50 at +2, $25 at zero or +1, and $10 at all negative counts.
Simulation result for benchmark rules:
win rate $16, standard deviation $415. Benchmark Win Rate As noted above, the benchmark win rate is $16 per 100 hands, with a standard deviation of $415. In a casino you will be able to play 50 to 300 hands per hour, so 100 hands represents roughly an hour’s play. Throughout this book results are stated in dollars per hour, which really means dollars per 100 hands.
Sampling Error That $16 win rate is a simulation result, and thus is an estimate. Though it is an estimate for 600 million hands of blackjack, it still contains what statisticians call “sampling error.” That is, a different 600-million-hand simulation would result in almost but not quite the same number. The term used to describe the precision of an estimate is the standard error.
The standard error applicable to the $16 win rate is $0.20. The actual simulation result was $15.78, which was rounded because the pennies and dimes are not significant. So you should think of the $16 as meaning somewhere in the $15.38 to $16.18 range. It would be nice to have a smaller standard error of course, and the way to do that is to increase the sample size. That is the reason why the sample size was run up to 600 million hands — to reduce the standard error to a reasonable number.
Each of the win rates in this book has a standard error of less than $1. So if one rule is changed from the benchmark, and a simulation with the new rule yields a win rate of say $20 per hour, that rule increased the win rate by $4 per hour. That $4 can be thought of as the value per 100 hands to a card counter of that rule change. But it is not exactly $4 per 100 hands because both the $20 and the $16 are sample statistics with sampling error.
If you run your own simulation trying to duplicate these results you probably would get $4, but you could possibly get $3 or $5 as the value of the rule. And of course if you use a different bet scheme, a different counting system, make an occasional error, or play against a different number of decks or with a different number of players at the table, or with different penetration, the value to you might be different from $4 per hour.
Average Bet Size
The average bet size for the benchmark is $26.54. That is the average initial bet; it does not include additional amounts wagered on doubles, splits, and side bets such as insurance. That $26.54, plus or minus a penny or two, is the average bet size on all simulations reported in this book for six decks, penetration down to the last deck, and the high-low system.
Benchmark Risk
The standard deviation for 100 hands for the benchmark is $415. That is, the win rate may be $16 but any given 100 hands typically has a result considerably less than or more than $16. In repeated samples of 100 hands, 2/3 of the samples have wins of $16 plus or minus $415. Risk varies with the rules. Some rule changes mean more risk, and some mean less risk. Being able to double down more often (such as after splitting pairs) means more risk, as represented by a higher standard deviation.
Restrictions on doubling down mean a lower win rate but that is partially offset by lower risk. Win Rates Reported Each simulation win rate in this book is reported in the form of win rate per 100 hands using the benchmark betting scheme, and the standard deviation applicable to 100 hands. The rest of the information pertaining to that simulation is the same as the benchmark as discussed above.
As an example, if one deck with penetration 26 cards is used instead of six decks, but everything else kept the same as the benchmark, the win rate is $48 and a standard deviation of $482. That means the simulation win rate averaged $48 per 100 hands, and the standard deviation describing the ups and downs in 100 hands was $482.
Effects on Win Rates
One Deck Two Decks Six Decks Raw Diff Raw Diff Raw Diff
Benchmark 48 19 16
Dlr hits soft 17 42 -6 13 -6 11 -5
Double after split 51 3 23 4 20 4
Double 10 & 11 only 38 -10 12 -7 10 -6
Double 9, 10, & 11 44 -4 16 -3 12 -4
Late surrender 54 6 23 4 21 5
Early surrender 77 29 42 23 39 23
Lose all to dlr BJ 42 -6 15 -4 11 -5
No insurance 41 -7 16 -3 14 -2
No resplits 47 -1 18 -1 15 -1
Over/under 13 78 30 31 12 32 16
Bustout 96 48 42 23 30 14
Plr BJ beats dlr BJ 59 11 28 9 26 10
Dealer’s 10 up + ace is ordinary 21 56 8 25 6 24 8 6-card win 51 3 22 3 18 2
Winning 5-card 21 wins double 50 2 21 2 17 1
5-card half win 63 15 33 14 30 14
Double on any number of cards, including after splits 61 13 28 9 26 10
42 cards not used (21 on single deck) 59 11 27 8 20 4
62 cards not used (31 on single deck) 33 -15 10 -9 13 -3
Hi-opt count 40 -8 13 -6 12 -4
Halves count 50 2 20 1 17 1
Basic strategy with high-low for bet variation 37 -11 14 -5 12 -4
Source:
Excerpt from 'Professional Blackjack', Author: Stanford Wong
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Basically, a $2-$10 game. Dealers use an 8-deck shoe. When done, we simply bring them a new, pre-shuffled shoe and take out the old shoe. This saves table down time by more than 25%. No insurance bets (I don't know why). Here's the big one...HOUSE TAKES TIES!
Two questions....
1. On average, based on what I just described, approximately how many hands should be played per-hour? This assumes a moderately skilled dealer.
2. By taking ties, approximately how much does that increase the house edge?
As always, thanks.
Administrator
Two questions....
1. On average, based on what I just described, approximately how many hands should be played per-hour? This assumes a moderately skilled dealer.
2. By taking ties, approximately how much does that increase the house edge?
As always, thanks.
Blackjack Average Hands Per Hour Table
My answers, could be wrong (my errors, not people I'm quoting)1. With no down time for shuffle, a moderate dealer should be able to deal a full table at 70-80 hph. (anecdotal from a distributor conversation)
2. Per the Wiz, house takes ties for all hands increases house edge by 8.86%. See this link, last line of the table.
I help run a charity gaming event. Real money. Low stakes. All volunteer dealers in blackjack. 20 tables which are always full w/7 players per table.
Basically, a $2-$10 game. Dealers use an 8-deck shoe. When done, we simply bring them a new, pre-shuffled shoe and take out the old shoe. This saves table down time by more than 25%. No insurance bets (I don't know why). Here's the big one...HOUSE TAKES TIES!
Two questions....
1. On average, based on what I just described, approximately how many hands should be played per-hour? This assumes a moderately skilled dealer.
2. By taking ties, approximately how much does that increase the house edge?
As always, thanks.
Great question, Riva! Hands per hour can be dealer dependent as some are faster and more dexterous than others. Other factors are number of players at the table, side bets, players' decision times etc. I regularly play over 200 hands per hour one on one.
Blackjack Average Hands Per Hour Poker
Wong did some studies on this subject using Atlantic City six deck games. Here's what is in Professional Blackjack:1 player: 248 hands per hour
2 players: 158
Blackjack Average Hands Per Hour Zone Poker
3 players: 116
4 players: 91
5 players: 76
6 players: 64
7 players: 56
Yes, many tables were cramped with 7 spots back then. I hope that you find this even a little helpful. Working with charities is one of the most noble and rewarding things that I can think of. The very best of luck with yours.